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Update of the Residential and Non-residential Building Stock Renovation
Strategy, Slovak Republic
Bratislava, 24 April 2017
2
Contents
Introduction 3
1. Background and current approach to the renovation of buildings in Slovakia, market
characteristics 3
1.1 Current approach to the renovation of buildings 3
1.2 Background to the renovation of buildings 6
1.2.1 Renovation of residential buildings 6
1.2.2 Renovation of non-residential buildings 7
2. Underlying background to the public and private building stock renovation strategy (for
residential and non-residential buildings) 8
2.1. Overview of building stock, broken down by category 8
2.1.1. Residential buildings 9
2.1.1.1. Multi-apartment buildings 9
2.1.1.2. Single-family buildings 11
2.1.2. Non-residential buildings 13
2.1.2.1. Buildings owned by central and local government bodies 13
2.1.2.2. Buildings of central bodies of state administration 14
2.2. Cost-effective approach to building renovation according to the building category and
climatic zone 15
2.3. Procedures and measures to promote cost-effective deep renovations 17
2.4. Expectations and scope of renovation of residential and non-residential (public and
private) buildings to guide the investment decisions of individual investors, the
construction industry and financial institutions 18
2.4.1. Scope of residential building renovation expected 18
2.4.2. Scope of non-residential building renovation expected 19
2.5. Evidence-based estimate of expected energy savings and other benefits 19
3. Mobilisation of investment in public and private building stock renovation (for residential
and non-residential buildings) 20
3.1. Existing forms of building support 20
3.1.1. Existing forms of residential building renovation support 20
3.1.2. Existing forms of non-residential building renovation support 22
3.2. Requirements concerning the forms of residential and non-residential building
support from 2014 23
3.2.1. Requirements concerning the forms of residential building support from 2014
23
3.2.2. Requirements concerning the forms of non-residential building support from
2014 26
4. Tasks for the construction industry, the business community, employment and improved
qualifications arising from the strategy 27
4.1 Projects to improve qualifications in the construction sector after 2014 30
4.1.1 StavEdu project 30
4.1.2 ingREeS project 30
4.1.3 The BIM phenomenon in the construction industry 31
5. Review of the strategy’s implementation outputs 31
6. Barriers and obstacles 31
7. Conclusions 32
Annexes 33
3
Introduction
The requirement to draw up a strategy for the renovation of residential and non-
residential buildings in Slovakia stems from Directive 2012/27/EU of the European
Parliament and of the Council of 25 October 2012 on energy efficiency, amending Directives
2009/125/EC and 2010/30/EU and repealing Directives 2004/8/EC and 2006/32/EC,
transposed into Slovak legislation by Act No 321/2014 on energy efficiency and amending
certain laws. Article 4 of that Directive directs Member States of the European Union to
establish a long-term strategy for mobilising investment in the renovation of the national stock
of residential and non-residential buildings, both privately and publicly owned,1 and to update
it every three years.
The Update of the Residential and Non-residential Building Stock Renovation
Strategy, Slovak Republic, includes an overview of the national stock of residential and non-
residential buildings, the identification of cost-effective approaches to renovations relevant to
the building type and climatic zone, policies and measures to stimulate cost-effective major
(deep) renovations of buildings, including staged (deep) renovations. It contains a forward-
looking evidence-based estimate of expected energy savings and other benefits of renovations
of residential and non-residential buildings to guide the investment decisions of individuals,
the construction industry and financial institutions in Slovakia. In addition to the above, it
updates guidance on education related to relevant professions for the construction of energy-
efficient buildings according to the increasing minimum requirements for the construction
thereof.
The obligation deriving from Article 5 of Directive 2012/27/EU, that each Member
State shall ensure that, as from 1 January 2014, 3 % of the total floor area of heated and/or
cooled buildings owned and occupied by central bodies of state administration is renovated
each year, is implemented according to an annually produced plan for the renovation of
relevant buildings. These buildings should be renovated so that they meet at least the
minimum energy performance requirements set by the relevant Member State further to
Article 4 of Directive 2010/31/EU of the European Parliament and of the Council of 19 May
2010 on the energy performance of buildings (recast).
The update respects the requirements arising from Article 4 of Directive 2012/27/EU,
taking into account the related conditions set out in the ‘Assistance Documents for EU
Member States in developing long-term strategies for mobilising investment in building
energy renovation (CA EED, CA EPBD and CA RES)’ and the observations presented in the
‘Synthesis Report on the Assessment of Member States’ Building Renovation Strategies’.
1. Background and current approach to the renovation of buildings in Slovakia,
market characteristics
1.1 Current approach to the renovation of buildings
A systemic approach to building renovation was adopted in Slovakia in the late 1990s,
when it was found that features common to buildings older than 30 years built in Slovakia,
for the most part, between 1960 and 1992 in collective forms of construction were the
1 According to Directive 2012/27/EU: residential and commercial buildings, both public and private.
4
insufficient thermal protection of the structures and the high degree of wear found in the
buildings’ technical equipment, which needed to be urgently replaced with components of a
quality and properties that would create the required safety and well-being in these buildings
for their further viable life. Another common negative feature comprised the static and
technical shortcomings of building structures, influenced by the initial technical design, the
method of implementation, and, in particular, the lack of maintenance and repair.
All of these residential and non-residential buildings, erected according to design
documents with substantial levels of repetitiousness, were constructed up to 1992, i.e. they
have been in use for over 20 years. This period of occupancy is borne out by the fact that a
large proportion of these structures and technical facilities are approaching the end of their
viable life. The need for renovation is also corroborated by changes in legislation and, in
particular, technical regulations relating to the essential requirements of static, fire and user
safety, hygiene, health and the environment, as well as acoustic protection, energy savings
and thermal protection.
Associated with the renovation strategy are concepts defining the scope of renovation,
draft cost-effective measures, and, consequently, the estimated costs and expected energy
savings. These concepts are defined in Annex 1.
The Ministry of Construction and Public Works of the Slovak Republic2 prepared and
submitted a Building Renovation Concept with an Emphasis on Housing Stock Renovation,
which was approved under Government Resolution of the Slovak Republic No 1088 of
8 December 1999. The scope of residential and non-residential buildings is shown in Table 1.
Table 1
Total building
stock
Up to
1950
1951
to
1960
1961
to
1970
1971
to
1980
1981
to
1990
1991
to
2000
Total
built-up volume of buildings (m3 millions)
Non-residential
buildings 20.95 14.29 22.86 53.33 63.81 34.01 209.25
Residential
buildings 44.11 29.52 47.00 88.82 87.51 32.76 329.72
Buildings, halls for
manufacturing and
services
55.96 41.45 64.28 117.00 143.83 58.11 480.63
Total 121.02 85.26 134.14 259.15 295.15 124.88 1 019.60
Source: Building Stock Renovation Concept with an Emphasis on Housing Stock, Ministry of Construction and
Public Works/VVÚPS-NOVA (Surface Structure Research and Development Institute), 1999; amendments for
the years 1998-2000 by ÚEOS-Komercia, a.s., Bratislava
According to the Building Stock Renovation Concept, the initial procedural action was
to fix systemic defects in multi-apartment buildings built according to specific types,
structural systems and building systems (‘structural systems’). The number of systemic
2 For the Ministry of Construction and the Construction Industry, the Ministry of Construction and Public
Works, the Ministry of Construction and Regional Development, the Ministry of Transport, Construction and
Regional Development, the Ministry of Transport and Construction (the ‘Ministry’).
5
defects was extended from the originally proposed 6 to 11 in 2002, rising to 12 systemic
defects in 2006. The second procedural step was to employ renovation as a means of
addressing static, hygienic and user flaws in multi-apartment buildings more than 30 years
old. The third procedural step was to renovate multi-apartment buildings built in the last 30
years. Government Regulation No 587/2001 amending Government Regulation No 137/2000
on housing programmes, which implemented the Act on the State Housing Development
Fund, revised the criterion used to support the renovation of multi-apartment buildings,
bringing the age down from 30 years to 20 years. This also potentially altered the number of
apartments in multi-apartment buildings built en masse that were eligible under the renovation
scheme. Besides the age of a multi-apartment building, scheme eligibility was also contingent
on a 20 % reduction in the heat consumed on space heating compared to the original situation.
Financial support for the thermal insulation of buildings was linked to conditions
deriving from Resolution of the Government of the Slovak Republic No 493/1991, on the
basis of which, in October 1991, the Ministry drew up a Directive on Procedures and
Specifications for the Additional Insulation and Removal of Faults in Multi-apartment
Buildings.
Since 1996, loans have been available from the State Housing Development Fund for
the insulation of residential buildings. The numbers of renovated residential buildings
(apartments) supported by the housing development scheme and the State Housing
Development Fund are presented in Annex 2.
The terms and conditions applicable to the State Housing Development Fund’s loans
for residential building renovation are currently governed by Act No 150/2013 on the State
Housing Development Fund (Section 6(1)(c) of the Act). Under that Act, loans are granted for
the renovation of residential buildings entailing the modernisation or reconstruction of the
common parts of a multi-apartment building and the common facilities thereof, the removal of
a systemic defect in a multi-apartment building, or structural alterations to a multi-apartment
building or a separately used part thereof or to a single-family building involving the thermal
insulation of the external skin and/or roof cladding and the replacement of the original
external doors and windows of a multi-apartment or single-family building (‘residential
building insulation’). Similarly, insulation loans are granted for the renovation of social
service facilities.
Terms and conditions were drawn up as early as 2000 to promote the elimination of
systemic defects in multi-apartment buildings by means of external skin insulation. In the
period from 2000 to 2016, subsidies totalling approximately EUR 106 462 000 were granted
for 147 397 apartments.
Terms and conditions applicable to subsidies for the elimination of systemic defects in
multi-apartment buildings are currently governed by Act No 443/2010 on housing
development subsidies and on social housing, as amended.
The launch of action to eliminate systemic defects in the housing stock was a very
urgent matter. Financial resources were also gradually released for loans (via the State
Housing Development Fund) intended for the renovation of residential buildings. No systemic
action for the renovation of non-residential buildings had been drawn up by 2014. Structural
and private resources were used to cover the partial renovation of selected categories of non-
residential buildings.
6
A common approach to improving the energy performance of buildings in the
European Union, and in particular to significantly reducing CO2 emissions through buildings,
was laid down in Directive 2002/91/EC of the European Parliament and of the Council of
16 December 2002 on the energy performance of buildings and Directive 2010/31/EU, which
were transposed into Slovakia’s legal and technical regulations. The method for the
implementation thereof was addressed initially in the Building Energy Performance Concept
up to 2010 with an Outlook up to 2020 (approved under Resolution of the Government of the
Slovak Republic No 384/2008) and, subsequently, in the Updated Building Energy
Performance Concept up to 2010 with an Outlook up to 2020, approved under Resolution of
the Government of the Slovak Republic No 336/2012. The proposed building renovation
strategy should serve as an umbrella for many of the new roles stemming from these concepts,
currently encompassing the years 2015 to 2020. The results of the scientific and technical
service ‘Technical and economic aspects of cost-optimal measures to safeguard the energy
performance of buildings’ will also be used. Those results reflect conditions and procedures
under Commission Delegated Regulation (EU) No 244/2012 of 16 January 2012
supplementing Directive 2010/31/EU of the European Parliament and of the Council on the
energy performance of buildings by establishing a comparative methodology framework for
calculating cost-optimal levels of minimum energy performance requirements for buildings
and building elements, which complements Directive 2010/31/EU.
1.2 Background to the renovation of buildings
1.2.1 Renovation of residential buildings
Since 1992, Slovakia has targeted the renovation of housing stock which is more than 20
years old, in particular by installing thermal insulation and removing static deficiencies. The
construction of prefabricated multi-apartment buildings came to an end in 1993. All of these
residential buildings should gradually be renovated. This policy is based on the underlying
observation that building stock younger than 20 years old undergoes periodic maintenance
and upkeep, whereas building stock older than that requires renovation.
The Statistical Office of the Slovak Republic and other institutions have yet to carry
out statistical evaluations of individual building works (e.g. the thermal insulation of external
walls). Nor does Slovakia engage in the statistical year-on-year monitoring of completed
buildings that are being renovated to determine whether they are residential or non-residential
buildings. The Statistical Office first addressed building renovation (insulation) in detail in the
2011 Population and Housing Census. Here, it extended the tracking of building data to
include the items ‘Thermal insulation’ (the insulation of external walls and the replacement of
windows) and ‘Scope of reconstruction’.
It should be borne in mind that the precision of the data collected is skewed by the
way the question has been worded and by the way owners subjectively and individually assess
the scope of the renovation or insulation of their building. Data from the 2011 Census
(Annex 3) show that 27 % of single-family buildings and 41.04 % of multi-apartment
buildings had been renovated (at least partially) as at 21 May 2011. These figures were
distorted somewhat by the number of unoccupied apartments and buildings, i.e. 15 % of
single-family buildings and 5.75 % of multi-apartment buildings.
7
The scope of building renovation (insulation) forms a basis for us to compare the
results for Slovakia as a whole and also to address regional differences (Table 4, Annex 3).
The extent of single-family building renovation is highest in the Bratislava Region (41.86 %)
and Žilina Region (33.08 %), and lowest in the Banská Bystrica Region (19.55 %) and Nitra
Region (22.97 %). The situation is much the same for multi-apartment buildings, with as
many as 53.13 % renovated in the Žilina Region, followed by 50.25 % in the Bratislava
Region, while the Košice Region (31.21 %) and the Nitra Region (32.04 %) languish at the
other end of the scale. The expert estimate of building renovation, drawn up by the Building
Insulation Civic Association (Občianske združenie pre zatepľovanie budov) by reference to
the progressively updated mechanism detailing thermal insulation installed in the external
skin of buildings from 1992 to 2012, can be compared with data from the 2011 Census. The
Building Insulation Association’s original figures can then be adjusted accordingly
(paragraphs 2 and 3 of Annex 3).
Once the Building Insulation Association’s figures had been adjusted, it was also
possible to calculate the scope of renovation (insulation) for the period from 2011 until the
end of 2016. This showed that, taking Slovakia as a whole, more than 58 % of multi-
apartment buildings and 37.5 % of single-family buildings had been renovated. We assume
that the stated number of renovated single-family buildings and multi-apartment buildings
includes some buildings where only partial renovation has been carried out.
Table 2 Apartments in multi-apartment and single-family buildings renovated up to
31 December 2016
Description
Apartments in
multi-apartment
buildings
Apartments in
single-family
buildings
Total
2011 Census 931 605 1 008 795 1 940 400
Renovation as at 2011 Census 382 319 272 415 654 734
Renovation as at 31 December 2016 543 406 378 271 921 677
Proportion of renovation as at
31 December 2016 (%) 58.33 37.5 47.5
Source: Data from the 2011 Census (Statistical Office), prepared by the Building Insulation Association
1.2.2 Renovation of non-residential buildings
The extent to which non-residential buildings have been renovated has not yet been
statistically monitored in Slovakia. This is due in part to the fact that national support schemes
to promote the renovation of non-residential buildings have not yet been prepared.
Under the Operational Programme Basic Infrastructure 2004-2006, 178 buildings were
renovated, of which 86 were school buildings, 28 were healthcare buildings, 26 were social
service facilities and 38 were cultural buildings. This programme did not specifically focus on
building renovation or energy savings.
In 2012, 610 projects under Measure 1.1, Priority Axis 1 Education Infrastructure, of
the 2007-2013 Regional Operational Programme were duly completed (506 primary schools,
56 nursery schools and 48 secondary schools); 21 projects were completed under Priority
Axis 2 Social Service, Social Protection and Social Care Infrastructure; six projects were
8
completed and 45 were in progress under Measure 3.1, Priority Axis 3 Reinforcement of the
Cultural Potential of the Regions and Tourism Infrastructure; and 77 projects were duly
completed under Measure 4.2, Non-commercial Rescue Services, Priority Axis 4 Estate
Regeneration.
Financial resources disbursed by the Bohunice V1 International Decommissioning
Support Fund were used to implement the pilot project ‘Energy Efficiency in Public
Buildings’, under which 57 buildings were renovated (18 nursery and primary schools, 35
municipal authorities and community buildings and four healthcare centres) in the Trnava and
Nitra Self-governing Regions. Between 2008 and 2012, the EkoFond supported
improvements in the energy performance of 61 school and school-facility buildings and 21
public-service buildings. Between 2005 and 2012, approximately 2 387 500 m² of external
skin was insulated in the renovation of non-residential buildings.
Energy performance certificate issued since 2008 offer some indication of the scale of
renovation. Since 2010, the central register has contained records of energy performance
certificates classified by building category and the energy class achieved. According to the
number of energy performance certificates issued, between 2010 and 2016 a total of 3 911
buildings were renovated, of which 1 105 were office buildings (28.25 %), 1 069 were the
buildings of schools and school facilities (27.33 %), 599 were commercial-service buildings
(15.32 %), 391 were the buildings of hotels and other accommodation facilities (10 %), 121
were hospital buildings (3.1 %), 95 were sports halls and the buildings intended for sport
(2.42 %) and 531 were other mixed-purpose buildings (13.58 %). More detailed results on
the number of buildings renovated under energy performance certificates are presented in
Annex 4.
2. Underlying background to the public and private building stock renovation
strategy (for residential and non-residential buildings)
2.1 Overview of building stock, broken down by category
Buildings (heated and cooled) have an impact on long-term energy consumption.
Buildings account for approximately 40 % of energy consumption. Given the long renovation
cycle for existing buildings, new, and existing buildings that are subject to major renovation,
should therefore meet minimum energy performance requirements adapted to the local
climate.
The results of the statistical processing of the 2001 Census and the 2011 Census, along
with the Building Testing and Research Institute (TSÚS) database of residential and non-
residential buildings (for the years 1994 to 2003), are the underlying sources for the
preparation of the housing stock overview. Data characterising buildings and the heat they
consume on space heating can only be accessed from the above database and account for a
large proportion of the buildings mentioned in the 2011 Census. These data form a basis when
determining the renovation strategy. The construction of buildings built after 2002 should
comply with new requirements derived from the revised set of STN 73 0540 heat standards
and parts, revised in 2012, of STN 73 0540-2 Thermal performance of structures and
buildings. Thermal protection of buildings. Part 2: Functional Requirements, and STN
9
73 0540-3 Thermal performance of structures and buildings. Thermal protection of buildings.
Part 3: Properties of the environment and construction products, for structures and buildings.
Built-in structures and technical systems have an estimated service life of at least 20 years (for
more details, see Annex 5).
2.1.1 Residential buildings
Residential buildings are divided into multi-apartment buildings and single-family
buildings. Their design and technical solutions are different. As a matter of principle, they
differ in size, number of storeys and number of apartments.
The properties of structures and their share in the overall area of the building envelope
are different, resulting in different heat and energy requirements for space heating in these
buildings, measured per unit of floor area. The number of existing buildings and their age
should be used as factors when determining the potential to reduce energy needs.
Construction in individual years of the second half of the 20th
century was influenced by the
availability of various building materials and structures, and by the controlled construction
process using standardised and prefabricated designs.
Table 3 Aggregate data on buildings and apartments according to the 2011 Census
Description Single-family
buildings
Multi-apartment
buildings Total
Number of buildings 969 360 64 846 1 034 206
Total number of
apartments 1 008 795 931 605 1 940 400
Number of apartments
occupied 856 147 877 993 1 734 140
Source: 2011 Census, Statistical Office
Besides multi-apartment and single-family buildings, apartments can also be found in other
buildings (religious institutions, social-service buildings, retirement homes, etc.), of which
there are 13 020, equating to a 3.41 % share. These buildings accommodate 54 497
apartments.
Most of this housing stock was built between 1960 and 1983 and is therefore more than 30
years old. Construction work carried out up to 1983 (inclusive) incorporated very poor
thermal performance due to the requirements applicable at the time and the technological
capacities of construction.
2.1.1.1 Multi-apartment buildings
Multi-apartment buildings can be characterised by the period in which they were
constructed. Between 1947 and 1992, mass housing construction saw the erection of multi-
apartment buildings of various set types, construction systems and structural systems (existing
buildings), with a particular inclination for prefabricated concrete technology (large-panel
system buildings). After 1992, atypical buildings started to be designed on an individual basis
10
0
50000
100000
150000
200000
250000
300000
Num
ber
of
apart
ments
Years of construction
(new buildings). More precise data on the construction of apartments in multi-apartment
buildings up to 1992 could be drawn from the 2001 and 2011 Censuses.
Figure 1 – Number of apartments in multi-apartment buildings (source: Science and
Technology Service – cost-optimal proposals of minimum requirements for the energy
performance of buildings, Building Testing and Research Institute)
In view of the thermal performance of the external skin and the construction
technology, multi-apartment buildings can be broken down into five groups which, in the
various periods, were influenced by requirements regarding the properties of building
structures. These differ by the thermal properties of envelope structures, their share in the
surface area of the building envelope, and energy requirements or actual energy consumption.
Table 4 Number of buildings, apartments, sections and specific area by group (type,
construction system and structural system)
Type of structural system, construction
system
Number
of buildings
Number
of apartments
Number
of sections
Total floor
area (m2)
Brick and pre-assembled masonry panels 6 761 133 814 14 447 10 733 966
Single-layer large-panel system, built
between 1955 and 1983 7 983 374 503 20 284 29 807 256
Multi-layer large-panel system, built
between 1971 and 1983 2 131 96 298 5 878 8 234 737
Large-panel system, built between 1983
and 1998 3 646 183 402 9 415 16 159 811
Atypical buildings built from 1992 65 996 117 58 776
Other, unspecified 1 137 11 621 2 355 427 121
Total 21 723 800 634 52 496 65 421 666
Source: Slovak Report for the Commission (EU). Reference Buildings. Determination of Cost-optimal Levels of
Minimum Energy Performance Requirements, 2013
Multi-apartment buildings built up to 2001 can be found in only 567 Slovak
11
municipalities (i.e. in the form of buildings with more than three apartments). Multi-apartment
buildings constructed en masse took the form of terraced houses, slab blocks, point blocks and
tower blocks in any of 61 different types, construction systems and structural systems. 43.2 %
of apartments are located in multi-apartment buildings with up to four floors, and only 15 %
of apartments are located in multi-apartment buildings with more than eight floors. In
particular, this results in different renovation costs.
Most multi-apartment buildings are located in an area with a winter design
temperature of -11 °C (308 212 apartments), -13 °C (163 195 apartments) and -15 °C
(186 437 apartments). Only 23 multi-apartment buildings are located in sites with a
temperature of -19 °C (274 apartments). All of the coldest areas where multi-apartment
buildings have been constructed are located in the Prešov and Žilina Higher Territorial Units.
Of the 21 723 multi-apartment buildings, only 1 147 are located at an altitude more than
600 m above sea level and only 175 are at an altitude of more than 800 m above sea level.
The most recent comprehensive surveys show that the average annual heat
consumption for space heating between 1994 and 2003 in multi-apartment buildings was
131.7 kWh/(m2.a) for buildings made from brick and pre-assembled masonry panels,
110.3 kWh/(m2.a) for buildings made using single-layer large-panel systems (built between
1955 and 1983), 119.0 kWh/(m2.a) for buildings made using multi-layer large-panel systems,
and 101.9 kWh/(m2.a) for buildings made using large-panel systems constructed after 1983.
The results obtained for buildings constructed after 1983 and up to 1992 were used, following
a statistic evaluation thereof, to determine the upper limit of energy class B in the energy
performance of buildings in 2006. The actual energy consumed on space heating is influenced
by climatic conditions, which can vary significantly in Slovakia. More detailed information
on multi-apartment buildings is presented in Annex 6.
Apertures (building structures with the worst thermal performance) over the building
envelope account for a large share of energy consumption. They range approximately from
13 % to 25 % of the overall area of the building envelope and from 19 % to 32 % of the area
of the external skin. Apertures in the original construction are a major point of heat loss in a
building.
2.1.1.2 Single-family buildings
Single-family buildings are variable in their shape, shape factor values and share of
individual structures in the thermal envelope. Detailed statistics and databases with data on
single-family buildings are not available. Only the number of single-family buildings built in
each period, as reported in the 2001 and 2011 Censuses and published by the Statistical
Office, is available.
12
0
20 000
40 000
60 000
80 000
100 000
120 000
140 000
160 000
180 000
200 000
Years of construction
Num
ber
of apart
ments
Figure 2 – Numbers of apartments in single-family buildings according to statistical data,
Statistical Office
To determine more detailed typical geometric characteristics of single-family
buildings, the set of representative single-family buildings used to determine the scale for the
energy certification of buildings in the handling of research and development tasks, as
commissioned by the Ministry, could be used as a basis. The habitable areas of single-family
buildings are known from the statistics. The ratio between the habitable area and the total
floor area varies and depends on the layout of the single-family building. The ratio of the
habitable area to the total floor area was set at 75 %.
Table 5 Average size of the habitable area and total floor area of single-family
buildings Single-family buildings
Location of apartment, by
storey
Average number of
habitable rooms per
apartment
Average habitable area
per
apartment (m2)
Average adjusted total
floor area per
apartment (m2)
Ground floor 3.32 60.6 80.8
Ground floor and first
floor
4.83 87.4 116.5
First floor 3.53 65.1 86.8
Second floor 4.08 75.2 100.3
Source: Slovak Report for the Commission. Reference Buildings. Determination of Cost-optimal Levels of
Minimum Energy Performance Requirements
Owing to their large envelope area compared to their built-up volume (shape factor),
single-family buildings require more heat for space heating than multi-apartment buildings.
The minimum shape factor for single-family buildings is 0.6 1/m; the maximum is 1.11 1/m.
The total floor area per apartment in single-family buildings is approximately 1.5 to 2 times
the area per apartment in multi-apartment buildings.
No detailed data on the energy consumption of existing single-family buildings are
available. Based on the evaluations available, average annual energy consumption on space
heating of 165 kWh/(m2.a) can be assumed. However, it is not usual for all rooms to be heated
13
2003 2060
3725 3700
2385
1496
483
1401
3009 2884
2478
1216
0
500
1000
1500
2000
2500
3000
3500
4000
4500
Nu
mb
er o
f b
uild
ings
Bu
ilt-u
p v
olu
me
(ten
s o
f tho
usa
nd
s o
f m3)
Number and built-up volume of buildings, by age of building
Year of final approval
at once and therefore the actual energy consumption is lower.
The minimum share of the aperture area is 4.1 %; the maximum is 12.8 %. A large
proportion of this is taken up by roof structures, especially in single-family buildings with
sloping roofs.
2.1.2 Non-residential buildings
2.1.2.1 Buildings owned by central and local government bodies
Of the total number of non-residential buildings, between 1994 and 2003, 15 435
buildings were identified as being owned by central and local government bodies. Broken
down by built-up volume, 50.9 % of these non-residential buildings were schools, 13.2 %
were healthcare facilities, 12.5 % were office buildings and 10.3 % were accommodation
facilities.
Non-residential buildings owned by central and local government authorities account
for a 54.8 % share of the built-up volume of non-residential buildings identified to date (Table
7, Annex 6).
Figure 3 – Built-up volume of non-residential buildings owned by central and local
government bodies and number thereof, by age (source: Slovak Report for the Commission
(EU). Reference Buildings. Determination of Cost-optimal Levels of Minimum Energy
Performance Requirements, 2013)
Information on the average energy consumption on space heating is available only for
the period from 1994 to 2003. The average consumption at all non-residential buildings
owned by central and local government bodies is 55.2 kWh/(m³.a); for primary schools it is
only 49.1 kWh/(m³.a). The lower annual heat consumption of primary schools compared with
the average for all buildings is due to the lower average temperature of the indoor air in
schools, compared, for example, with office buildings or healthcare buildings, and the
relatively large number of holidays in the winter. The highest heat consumption is recorded by
14
the buildings of healthcare facilities, i.e. 68.3 kWh/(m³.a), and the lowest, at 42.7 kWh/(m³.a),
is recorded by the buildings of cultural facilities, which are often not heated all year round,
and the entire built-up volume is not heated. Sports facilities report low heat consumption at
44.3 kWh/(m³.a). These facilities generally comprise the gyms of primary and secondary
schools, which are heated to a lower temperature. Average energy consumption on space
heating has changed in recent years following the replacement of windows and the installation
of insulation. However, in more than a third of buildings arrangements are not in place to
reduce space heating at night and weekends. Besides space heating, most non-residential
buildings also use a lot of energy on lighting and hot water. Figures on actual consumption in
these areas of energy use are not available.
2.1.2.2 Buildings of central bodies of state administration
According to Article 5 of Directive 2012/27/EU, each Member State shall ensure that,
as from 1 January 2014, 3 % of the total floor area of heated and/or cooled buildings owned
and occupied by central bodies of state administration is renovated each year to meet at least
the minimum energy performance requirements that it has set in the application of Article 4 of
Directive 2010/31/EU.
Directive 2012/27/EU (Article 5(6)) also allows for an alternative approach to be taken
in the fulfilment of the obligation under Article 5(1). This means that a Member State may
take cost-effective measures, including deep renovations and measures for a change in the
behaviour of building occupants, to achieve, by 2020, energy savings in relevant buildings at
least equivalent to the volume of savings required in Article 5(1) of Directive 2012/27/EU;
Member States are to report on this to the European Commission on an annual basis.
Table 6 Number of buildings, total floor area and built-up volume of buildings of
central bodies of state administration
Data Number of
buildings
Total floor
area (m2)
Built-up
volume (m3)
Sum of all buildings 3 806 4 773 344 21 678 102
Sum of all buildings, by owner – area not specified 189 0 9 408
Buildings more than 500 m² 1 893 4 370 709 19 571 523
Buildings more than 500 m², from 1947 to 1993
(inclusive)
1 364 3 175 872 14 026 720
Buildings more than 500 m² – year not specified 62 112 392 536 336
Buildings more than 500 m² – up to 1947 135 365 202 1 860 893
Buildings more than 250 m² (including those
more than 500 m²) 2 631 4 641 021 21 070 474
Buildings more than 250 m², from 1947 to 1993
(inclusive)
1 938 3 386 048 15 178 299
Buildings more than 250 m² – year not specified 1938 3 386 048 15 178 299
Buildings more than 250 m² – up to 1947 192 385 754 1 000 936 Source: Ministry of Transport, Construction and Regional Development – Report notifying an alternative
approach in accordance with Article 5 of Directive 2012/27/EU
A list of relevant (eligible) buildings of central bodies of state administration, in
accordance with Article 5 of Directive 2012/27/EU, is published on the Ministry’s website at
15
http://www.telecom.gov.sk/index/index.php?ids=170474.
The notification report informs the European Commission of alternative measures
planned in the pursuit of the energy savings target up to 2020 in accordance with Article 5(6).
The report includes a draft preliminary target in accordance with Article 5(1), a target
expressed as energy savings for the purposes of applying the alternative approach, and a list
of the alternative measures.
The determining factor in the preparation of the list of buildings for the
implementation of the obligation to deep-renovate buildings of central bodies of state
administration is a total floor area of more than 500 m². From 9 July 2015, this area was
reduced to 250 m². The annual target in accordance with Article 5 of Directive 2012/27/EU is
3 % of the total floor area of the buildings listed.
2.2 Cost-effective approach to building renovation according to the building
category and climatic zone
The proposed cost-effective measures for improvements in the energy performance of
buildings are linked to deep renovations. During deep renovations, attention needs to be paid
– in addition to building stock structures and their major renovation (improvements in the
thermal protection of structures) – to the major renovation of buildings’ technical systems, i.e.
the space heating system and hot water system for residential and non-residential buildings, as
well as the ventilation, cooling and lighting of non-residential buildings.
The publication of the ‘Draft methodology and input data for the determination of the
cost-effectiveness of the construction and renovation of buildings in terms of energy
performance’ provides guidance. This document focuses on determining input data on
construction products and technical systems in order to define measures affecting the energy
performance of buildings at various levels of energy performance requirements. It is available
on the Ministry’s website at http://www.telecom.gov.sk/index/index.php?ids=82867 .
Improvements in the energy performance of buildings are also dependent on the
energy efficiency of heat and cold production. Slovakia has a well-developed district heating
system that covers more than 30 % of overall heat consumption (approximately 16 100 multi-
apartment buildings). Most heat sources and heat distribution systems were built prior to
1990. The boilers used in district heating systems vary considerably in terms of their age,
technical parameters and fuel type. Most of the boilers in operation are less than 15 years old.
Installed capacity is dominated by boilers more than 20 years old. District heating systems
tend to use warm water and hot water distribution systems. The bulk of heat distribution pipes
were installed 20-30 years ago, which is reflected in their technical condition. As the expected
service life of these sources and distribution systems is between 25 and 30 years, the major
renovation of technical equipment also encompasses heat and hot water production and
distribution.
Deep renovation may be carried out as partial measures, in the form of gradual steps,
or separately as the major renovation of a building (structures) and the major renovation of
technical systems. Deep renovation may also encompass all measures at once.
Draft measures are differentiated by:
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(a) the targets set to ensure the energy performance of buildings, as laid down by Act
No 555/2005 on the energy performance of buildings, as amended by Act
No 300/2012 and Implementing Decree No 364/2012;
(b) the building category (residential and non-residential buildings);
(c) the construction period (up to 1983, inclusive, up to 2002, after 2002);
(d) the original condition of structures (apertures, external skin, roof cladding and internal
partitions between heated and non-heated rooms);
(e) the original condition of technical systems in the building (space heating, hot water,
ventilation, cooling, lighting);
(f) the age and technical condition of sources of heat, hot water, cold and distribution
systems in and outside of the building;
(g) the extent to which renewable sources of heat, hot water and electricity have been
introduced.
The proposed cost-effective measures and improvements in the energy performance of
buildings are detailed in Annex 5.
Procedures for the evaluation of cost-effectiveness are laid down in the standard STN
EN 15 459 Energy performance of buildings. Economic evaluation procedure for energy
systems in buildings (06 0004). These procedures were also applied when determining the
cost-optimal levels of the minimum requirements for the energy performance of buildings in
accordance with Commission Regulation (EU) No 244/2012. When calculating the net
present value during the expected economic cycle, it is necessary to determine the initial
investment costs of implementing the measures and to set the calculation period and the life of
the individual measures (components), the replacement costs, the costs of maintenance and
economic activities, disposal costs, and the cost of heat, electricity and other energy carriers.
To maintain the cost-optimal level of minimum requirements for the energy
performance of buildings, greater stringency was introduced from 1 January 2016. The results
of the calculation of the cost-optimal levels were reported to the Commission in May 2013
and are published at http://ec.europa.eu/energy/efficiency/buildings/doc/sk_cost-
optimal_2013.
The following graph shows how the structural heat transfer coefficient, by level of
construction, has become more stringent.
17
Heat transfer coefficient for structures UN in W/(m
2.K)
External skin Roof envelope External windows and doors
Source: 25 Years of Insulation in Slovakia; 15 years of Activity by the Building Insulation Association, TSÚS,
n.o., August 2016
2.3 Procedures and measures to promote cost-effective deep renovations
The Ministry has prepared a National Plan to Increase the Number of Nearly Zero-
energy Buildings (the ‘National Plan’), designed to ensure that new construction after 2020 is
of the required standard. The National Plan has been published on the Ministry’s website at
http://www.telecom.gov.sk/index/index.php?ids=83491.
Interim targets to achieve the individual energy levels of construction have been laid
down in Implementing Decree No 364/2012 implementing Act No 555/2005 on the energy
performance of buildings and amending certain laws, as amended, encompassing three stages
as follows:
(a) the low-energy level of construction for new and renovated buildings from 1 January 2013,
equal to the upper limit of energy class B for the individual building categories;
(b) the ultra-low-energy level of construction for all new buildings from 1 January 2016, equal
to the upper limit of energy class A1, and for renovated buildings, assuming compliance
with cost-effectiveness conditions;
(c) the energy level of nearly zero-energy buildings for new buildings owned and managed by
public entities from 1 January 2019, and all new buildings from 1 January 2021, equal to
the upper limit of energy class A0 for the overall indicator (primary energy). This energy
level is also required, where technically, functionally and economically feasible, for
renovated buildings.
The heat required for space heating has a significant influence on space heating energy
requirements and hence on the overall energy needs of a building. The heat required for space
heating depends on the efficiency and quality of a building’s thermal protection. Standard
STN 73 0540-2 Thermal protection of buildings. Thermal performance of structures and
buildings. Part 2: Functional requirements (70 30540), defines requirements for energy-
efficient buildings (the maximum permitted values guaranteeing compliance with hygiene
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criteria), low-energy buildings (standardised requirements from 1 January 2013), ultra-low-
energy buildings (recommended values, applicable as standardised from 1 January 2016) and
nearly zero-energy buildings (target recommended values, applicable as standardised from
1 January 2021). Thermal protection is essential to safeguard the necessary level of
construction in terms of energy requirements.
New buildings must comply with standardised requirements for the thermal
performance of structures and buildings. Buildings undergoing major renovation must also
comply with standardised requirements. Where this is not functionally, technically or
economically feasible, all structures subject to major renovation must at least meet the
minimum requirements for energy-efficient buildings.
If a nearly zero level of energy requirements is to be achieved for all new and
renovated buildings, renewable energy sources must be used efficiently.
The cost-optimal levels of minimum requirements for the energy performance of
buildings were laid down in the Commission’s comparative methodology framework
established by Commission Regulation (EU) No 244/2012 and the Guidelines accompanying
Commission Regulation (EU) No 244/2012, supplemented with national parameters. The
objective pursued in the handling of the scientific and technical service was to prove, by
means of calculations and comparisons, whether the current requirements for the minimum
energy performance of buildings and building elements in Member States lag far behind than
the cost-optimal requirements. The results of a comparison show the merits of tightening
requirements after 2015 to 50 % of the 2013 level of requirements (Annex 7).
2.4 Expectations and scope of renovation of residential and non-residential
(public and private) buildings to guide the investment decisions of individual
investors, the construction industry and financial institutions
2.4.1 Scope of residential building renovation expected
Assuming financial resources are secured at the same level as in previous years
(approximately EUR 100 million per year), materials and staffing are in place to continue
building renovation at the same pace as in recent years.
The need to ensure more stringent energy levels of construction will also increase
demands on the quality of work related to the energy performance of buildings. Based on
experience to date and on adequate forms used to promote the renovation of residential
buildings, projections indicate that such renovation should continue at an annual tempo of
29 000 apartments in multi-apartment buildings and 22 000 apartments in single-family
buildings. The renovation of such a number of apartments should have covered, in 2020,
70.8 % of multi-apartment buildings and 45.5 % of single-family buildings.
At this rate of renovation, multi-apartment buildings in Slovakia should be renovated
in 2029, and single-family buildings in 2043. If we were to limit our forecasts solely to the
renovation of occupied single-family buildings, their renovation could be completed in 2036.
Table 7 Scope of residential building renovation expected after 2016
Description Apartments in multi- Apartments in
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apartment buildings single-family
buildings
2011 Census 931 605 1 008 795
Renovation as at 31 December 2016 543 406 378 271
Proportion of renovation as at
31 December 2016 (%)
58.33 37.5
Scope of renovation in 2017-2020 116 000 88 000
Scope of renovation as at 31 December 2020 659 406 458 946
Proportion of renovation as at
31 December 2020 (%)
70.8 45.5
Balance for 2021-2030 272 199 549 869
Number of years of renovation after 2020 9.4 25.0
Renovation of occupied apartments in single-family buildings after
2020
18.05
Source: Data from the 2011 Census (Statistical Office), prepared by the Building Insulation Association and
TSÚS
The tightening of requirements for the energy performance of buildings will require
the re-renovation of buildings already renovated in the past. If the energy performance of
buildings is to be improved, it is necessary to ensure the effective heat protection of
structures, with a positive impact on reductions in the need for heat to provide space heating.
The need for heat to provide space heating is affected in particular by the structural heat
transfer coefficient U in W/(m2.K). External skin insulation after 1992 entailed thermal
insulation in ETICS, primarily on the basis of 40-60 mm expanded polystyrene (EPS). The
thermal insulating function will be improved by increasing the thickness of the thermal
insulation, i.e. by doubling the ETICS. The required thickness of the thermal insulating layer
in the added ETICS must provide a level of thermal resistance equivalent to the difference
between the calculated value of the heat transfer coefficient of the original structure, including
the existing insulation, and the standardised (required) value.
All thermal insulation composite systems (ETICS) based on expanded polystyrene and
mineral wool can be proposed and installed provided that they have been issued with
documents associated with a European or national technical assessment (or, up to 1 July 2013,
certification) complying with the requirements of STN 73 2901 Installation of external
thermal insulation composite systems (ETICS) (73 2901).
2.4.2 Scope of non-residential building renovation expected
As the total floor area of the buildings of central bodies of state administration is
445 791 m² and every year 3 % needs to be renovated, 13 374 m² (Annex 2 to the Notification
Report) should be renovated, and the saving should be 52.17 GWh/year.
2.5 Evidence-based estimate of expected energy savings and other benefits
The potential for overall energy savings in residential and non-residential buildings up
to 2020 was first determined in the updated Building Energy Performance Concept up to 2010
with an Outlook up to 2020, approved under Resolution of the Government of the Slovak
Republic No 336 of 6 July 2012. The potential for energy savings anticipated an increase in
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the non-residential buildings renovated up to a level of a 3 % share of the total floor area of
such buildings per year. The fact that the scope of energy savings would be positively
influenced by the future renovation of non-residential buildings at a low-energy and ultra-
low-energy level was taken into account. The energy-saving potential in the period from 2011
until 2020, if the proposed measures were implemented for residential and non-residential
buildings, should have resulted in total energy savings of 15 222.8 TJ.
The conditions for determining the energy-saving potential were changed. The energy-
saving potential determined for the years from 2014 to 2016, with an outlook until 2030, is
based on measures proposed by the Ministry in the preparation of the third Energy Efficiency
Action Plan for 2014-2016 with an Outlook until 2020 (the ‘action plan’). The energy-saving
potential from the renovation of residential and non-residential buildings up to 2030,
established in this manner, is presented in Annex 8. The projected energy savings are
6 928.6 GWh.
3. Mobilisation of investment in public and private building stock renovation (for
residential and non-residential buildings)
3.1 Existing forms of building support
3.1.1 Existing forms of residential building renovation support
State housing policy concepts adopted after 1990 regulated an unequivocal task in
housing quality: to improve the technical condition of the existing housing stock and, using
appropriate renovation instruments, to contribute to the extended service life thereof and to
enhancements in the energy performance of buildings. These state housing policy concepts
paved the way for the Building Renovation Concept with an Emphasis on Housing Stock
Renovation, which was adopted as early as 1999 and has remained in force since. This
concept systemically addressed housing stock renovation to safeguard the housing policy
concept’s residential and non-residential building renovation targets.
In order to expand and enhance housing stock, in its housing policy the state currently
employs a system of economic instruments in the form of direct and indirect support.
(a) Direct state support for tasks associated with building renovation is provided in the
following form:
- direct subsidies under a housing development scheme, granted by the Ministry to
eliminate systemic defects in multi-apartment buildings;
- direct subsidies in the form of an allowance for the insulation of a single-family building,
granted to natural persons – owners of single-family buildings from 2016;
- soft loans granted to natural persons and legal persons via the State Housing Development
Fund, subject to compliance with statutory conditions.
(b) Indirect state support is available:
- under the Housing Stock Renovation State Support Scheme, in the form of bank
guarantees for loans (the ‘bank guarantee scheme’), which was approved by the Slovak
Government to revive housing construction and foster conditions conducive to the
renovation of housing stock;
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- as mortgage financing, where state support is provided in the form of a state contribution
to mortgages or a state contribution to mortgages for young people (this is only available
for natural persons);
- under a system of state-subsidised building society savings, where state support takes the
form of a state premium added to the building society savings of natural persons and
associations of the owners of apartments and non-residential premises.
The results of state support for the renovation of housing stock can be summed up as
follows:
(a) In the period from 2000 to 2016, subsidies totalling approximately EUR 101 462 000 were
granted to eliminate systemic defects in multi-apartment buildings with 141 397
apartments.
(b) In 2016, the single-family building insulation allowance was granted, after insulation had
been installed, for 14 single-family buildings in the amount of EUR 56 204.63; allowances
aggregating to EUR 526 500 were reserved for 81 single-family buildings ahead of such
insulation.
(c) State Housing Development Fund resources provided EUR 803 516 000 in support for the
renovation of residential buildings in 1996-2016, encompassing 183 276 apartments and
2 093 single-family buildings.
These are just the figures for renovation because, since 2014, in keeping with Act
No 150/2013 on the State Housing Development Fund renovation has encompassed
multiple support sub-purposes, including insulation, and the fund does not monitor these
sub-purposes separately.
(d) Between 2000 and 2013, bank guarantees were granted for loans totalling
EUR 43 019 000, intended for 26 852 apartments. Since 2013, no bank guarantees have
been provided for loans financing the renovation of housing stock.
(e) In the building society savings system, building societies grant approximately 80 % of
financial resources for the renovation of housing stock; expressed financially, this
translates into approximately EUR 280 million per year. Minor measures for the
modernisation and reconstruction of multi-apartment and single-family buildings account
for approximately 56 %.
Information on direct support for the renovation of residential buildings, as presented
in Annex 2, highlights the fact that building owners are aware of the need to eliminate
systemic defects prior to the renovation of the building itself or as an initial step in the
renovation process, as evidenced by the share of apartments in which systemic defects have
been removed (141 397 apartments).
One particular area where support for residential building renovation and residential
building insulation has so far proved to be of little effect is single-family buildings, the
number of which receiving support accounts for under 2 % of all apartments renovated. The
form of support and the conditions thereof for the renovation of insulated buildings, intended
to increase interest in the use of such support among single-family building owners, have
failed to make these new types of support – introduced in 2009 – more popular. Of the single-
family buildings insulated up to 2015, estimated to be more than 338 000, only 0.6 % have
been renovated with the use of financial support from the state.
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The forms of state support intended for single-family buildings were revised. It should be
borne in mind that the area of envelopes and apertures (the external skin and roof, as well as
windows), on a per-apartment basis, is at least four to six times larger per apartment; while
this requires a larger proportion of support, it results in greater energy-saving benefits per
apartment and, as such, the proportion of CO2 emission reductions per apartment is higher.
3.1.2 Existing forms of non-residential building renovation support
The support for residential building construction has not been mirrored by national
support schemes for the financial support of non-residential buildings in Slovakia.
Information published in the Building Energy Performance Concept up to 2010 with
an Outlook up to 2020, approved under Government Resolution No 384 in 2008, indicates
that a major step forward in the renovation of non-residential buildings was taken by the
implementation of the Operational Programme Basic Infrastructure, especially Priority 3
thereof (Local infrastructure for 2004-2006). The financial resources released, amounting to
SKK 1 872 258 937 (EUR 62 147 611), contributed to the renovation of 178 buildings, of
which 86 were school buildings, 28 were healthcare buildings, 26 were social service
buildings and 38 were cultural buildings. The required monitoring of information did not
focus on measures geared towards energy savings and, hence, the reporting of benefits
delivered by improvements in the energy performance of buildings.
Under a grant agreement signed in 2008 between the Ministry of Economy of the
Slovak Republic, the European Bank for Renovation and Development and the Slovak
Innovation and Energy Agency, other programmes were used to implement the pilot project
‘Energy Efficiency in Public Buildings’, under which 57 buildings were renovated (18
nursery and primary schools, 35 municipal authorities and cultural buildings and four
healthcare centres) in the Trnava and Nitra Self-governing Regions. The Bohunice V1
International Decommissioning Support Fund provided financial resources.
Financing for the energy performance of buildings from the private sector was
provided by EkoFond between 2008 and 2012; this primarily took the form of financial
support for municipalities as the founders of schools and school facilities or social, healthcare
and cultural facilities. As such, EkoFond contributed to improvements in the energy
performance of buildings at 61 schools and school facilities and 21 community buildings by
providing support of EUR 3 996 968. In addition, a programme call in 2008 supported energy
measures implemented at another 34 single-family and eight multi-apartment buildings at a
cost of EUR 597 457.
At an estimate, the energy performance of more than 300 non-residential buildings
was supported. This remains a very low proportion, with no focus on achieving major energy
savings in buildings. Neither the established conditions nor projects were rigorously centred
on achieving applicable minimum requirements for the energy performance of buildings, and
therefore the buildings renovated so far fall short of the criterion of major renovation.
The project Energy Audits, for more than 250 buildings owned or managed by
organisations throughout Slovakia funded fully or partly from the public purse, aims to
analyse the potential for savings and propose specific measures to reduce energy consumption
in public buildings.
23
Audit breakdown by building type:
161 office buildings;
79 school and school-facility buildings;
37 primary schools;
16 nursery schools;
26 secondary schools;
10 social-care buildings.
Each building type was assessed to determine whether the use of energy services with
guaranteed savings was also feasible. In practice, such projects are implemented if a return
can be made on the investment, in the form of energy cost savings, within about 10 years.
Municipalities, towns, higher territorial units and state institutions were able to use the
processed audits in the preparation of projects to finance measures proposed under support
mechanisms; they can also be used in the 2014-2020 programming period.
3.2 Requirements concerning the forms of residential and non-residential
building support from 2014
The strategic objective pursued by energy policy in Slovakia is to achieve a
competitive low-carbon energy industry delivering the safe, reliable and efficient supply of all
forms of energy at affordable prices, with due consideration for consumer protection and
sustainable development. The deep renovation of residential and non-residential buildings
paves the way for low-carbon energy industry, but requires sufficient motivation among the
owners of residential and non-residential buildings – with effective forms of financial support
for the renovation of buildings – in order to meet stringent minimum requirements for the
energy performance of buildings which also deliver the required economic returns.
3.2.1 Requirements concerning the forms of residential building support
from 2014
The State Housing Policy Concept up to 2020, approved under Government
Resolution No 13 of 7 January 2015, as the baseline document for housing up to 2020, lays
down the state’s comprehensive objectives for housing policy, defines the instruments to
achieve them, and formulates the responsibilities of citizens, the state, municipalities, higher
territorial units and the private sector in the provision of housing.
Through its instruments (the State Housing Development Fund), the state has long
supported the financing of priorities reflected in state housing policy in relation to the
expansion and enhancement of the housing stock. This support is mainly being channelled
into assistance for the procurement of rental apartments and into the renovation of residential
buildings.
There was also a seismic shift in the forms of state support intended for single-family
buildings. Act No 277/2015 amending Act No 443/2010 on subsidies for the development of
housing and on social housing, as amended by Act No 134/2013 and amending Act
No 555/2005 on the energy performance of buildings and amending certain laws, as amended,
which established subsidies to support improvements in the energy performance of single-
family buildings, was adopted in 2015. It has become clear, since the Act took effect, that the
24
amount of subsidisation needs to be increased, so an amendment is now being prepared that is
intended to push up this amount.
In the renovation of buildings, it is necessary to take into account the need to exploit
the full cost-effective potential of energy savings for a particular building, while bearing in
mind the long cycle of renovation, and, therefore, to engage in comprehensively major
renovation at the time such renovation is essential. Such major, or deep, renovation should
also factor in the efficient use of renewable energy sources.
For financing purposes, more use needs to be made of sources from the European
Union’s Structural Funds in the form of repayable financial assistance via the JESSICA
financial instrument because the implementation of measures focusing on improved energy
efficiency contributes directly to the pursuit of one of the main Europa 2020 objectives. There
are plans to use resources from the Integrated Regional Operational Programme 2014-2020
(within the scope of Priority Axis 4 Improvement in the quality of life in regions, with an
emphasis on the environment, Investment Priority 4.1: Support of energy efficiency, smart
energy management and the use of energy from renewable sources in public infrastructure,
including public buildings, and in the housing sector) for the renovation of residential
buildings, with an overall allocation of EUR 111.4 million (sourced from the EU), of which
EUR 101.4 million is earmarked for less-developed regions and EUR 10 million for a more
developed region.
In particular, to improve the living conditions of marginalised Roma communities in
the housing sector, it is possible to support their housing with financial resources from the
Operational Programme Human Resources, Priority Axis 6 Technical infrastructure in
municipalities where marginalised Roma communities are present, especially Investment
Priority 6.1. Provision of support for the physical, economic and social regeneration of
neglected urban and rural communities, Specific Objective 6.1.1 Growth in the number of
Roma households with access to improved housing conditions.
Another major source, apart from the central government budget, will be resources
from the sale of CO2 emissions, where the renovation of buildings is one of the most
significant sources of CO2 reductions and, therefore, proof of effective use in the investment
of these resources. The completed renovation of each residential building (multi-apartment or
single-family building), by means of the energy performance certificate delivered upon final
approval, can serve as proof not only of savings in overall energy, but also of the scope of
CO2 emission reductions.
Since July 2014, SlovSEFF III has distributed more than EUR 12.80 million to 29
projects. An annual reduction in greenhouse gas (CO2) emissions by 5.698 tonnes and an
annual energy saving of 32 025.93 MWh are expected. The carbon reduction compensation
(CRC), which is accepted as recognition of a future potential reduction in emissions, is
EUR 704 847. Extending this instrument will result in more projects being funded.
The EBRD has approved a EUR 60 million increase for the sustainable energy project
financing instrument SlovSEFF III. This means that a total of EUR 100 million is available in
the form of financial resources. The EBRD is deepening its support with a new loan extended
to Slovenská sporiteľňa, a.s. (SLSP) and VÚB Banka, a.s. (VÚB). In addition, another bank –
OTP Banka Slovensko, a.s. – will provide the EBRD with a credit line of EUR 10 million.
This credit line will allow the bank to provide financial resources to businesses and housing
25
cooperatives so that they can make sustainable investments in the energy sector in Slovakia.
The development of energy efficiency and renewable energy supplies demonstrates the
positive effects of rational energy use and a reduction in greenhouse gas emissions. It will
also help to reduce the high energy and carbon intensity in the region.
We expect the system of economic instruments currently in use, in the form of direct
and indirect support as presented in Section 3.1.1, to be continued in national support for the
renovation of residential buildings after 2014. The gradual tightening of conditions required to
achieve more demanding energy levels of construction will be reflected in revised
requirements for the granting of the corresponding financial support.
At present, the estimated absorption capacity for improvements in the thermal
performance of housing structures and the modernisation of building technical systems is
expected to comprise between EUR 250 million and EUR 350 million from public resources
(the Ministry, the State Housing Development Fund) for the 2014-2020 period, which is
insufficient. Approximately EUR 110 million needs to be earmarked from public resources
every year to cope with the projected rate of renovation of multi-apartment buildings in
Slovakia not only up to 2020, but beyond – up to 2030. Therefore, only around two thirds of
the financial resources required to renovate 29 000 apartments in multi-apartment buildings
every year will be covered. It follows that the gap in funding will have to be secured from
other sources, e.g. by drawing on financial resources from European funds, building societies,
commercial banks and other avenues open to the owners of apartments.
Annex 2 shows that the overall scope of support, if a subsidy covering 30 % of eligible
costs per renovated apartment in a single-family building were to be applied (capped at
EUR 6 000), would be reduced to a third for single-family buildings compared to the need for
credit facilities. Currently, an amendment to the law aimed at increasing the cap, probably
from 1 January 2018, is being proposed. This creates conditions for realistic future energy
savings and reduced emissions as a result of renovated single-family buildings; this is one of
the greatest energy-saving potentials in Slovakia in the future. Many related deficiencies in
single-family buildings would also be addressed by appropriate incentives to renovate such
buildings:
1. single-family buildings built prior to 1992 were generally self-help, unskilled projects
with numerous errors in design and construction;
2. today, the renovation of single-family buildings is often not carried out on the basis of
a building permit, the necessary design documentation is not drawn up, and energy
performance certificate are not submitted (in the reporting period from 2010 to 2013,
energy performance certificates were issued for only about a tenth of the single-family
buildings renovated);
3. the thermal protection of single-family buildings is not addressed sufficiently, crucial
details are not covered by design documentation and, hence, in construction, thermal
bridges are created; heat is leaked and hygiene deficiencies arise;
4. many single-family buildings are only partially insulated, and energy performance
certificate for the years from 2000 to 2013 prove that many such buildings, even
today, are only renovated in energy classes D, E or F;
5. there is scrimping on materials, unsuitable construction products are frequently used,
and the components of external thermal insulation composite systems (ETICS) are
26
replaced with others.
3.2.2 Requirements concerning the forms of non-residential building
support from 2014
In the long run, the European Union’s Structural Funds are a fundamental source of
financing for the development of Slovak businesses’ competitiveness and the attainment of a
competitive low-carbon energy industry; this also applies to the renovation of non-residential
buildings. There are plans to make use of the Structural Funds, in particular via the
Operational Programme ‘Quality of Environment’ and the Integrated Regional Operational
Programme 2014-2020. Under the Environmental Fund, in order to make use of proceeds
from the sale of emission allocations, the specification of subsidy-related support activities for
2014 was extended to include improvements in the energy efficiency of existing public
buildings, including insulation. This support encompasses the buildings of primary and
secondary schools, nursery schools/preschool facilities, community centres and municipal
authorities in the competence of municipalities, local government bodies, and their facilities.
In Member States of the European Union, the renovation of public buildings and, in
particular in this respect, the renovation of the buildings of central bodies of state
administration, should serve as an example for non-residential buildings. There are plans to
achieve the energy savings target set for the purposes of the alternative approach under
Article 5 of Directive 2012/27/EU by means of the following measures:
(a) increased energy efficiency in public sector buildings;
(b) energy auditing for public sector buildings or energy management;
(c) measures designed to change the behaviour of the occupants of buildings of central bodies
of state administration – the provision of advisory services, information and training
activities aimed at public sector buildings and the provision of energy management.
The measures are detailed in the Report notifying an alternative approach in
accordance with Article 5 of Directive 2012/27/EU on energy efficiency with the use of
relevant resources of the European Union’s Structural Funds.
Based on the structuring of the financial plan for the Operational Programme ‘Quality
of Environment’, approved under Resolution of the Government of the Slovak Republic
No 175 of 16 April 2014, and further to the Commission Implementing Decision of 11 June
2015 correcting Implementing Decision C(2014)8047 approving certain elements of the
operational programme ‘Quality of Environment’ for support from the European Regional
Development Fund and the Cohesion Fund under the Investment for growth and jobs goal in
Slovakia, European Union resources amounting to EUR 937 558 268 and national co-
financing of EUR 674 913 781 (a total of EUR 1 612 472 049) are being considered for less-
developed Slovak regions under Priority Axis 4, Thematic Objective 4 Energy-efficient low-
carbon economy in all sectors. The national co-financing for the more developed regions of
Slovakia is EUR 1 328 212 (a total of EUR 2 656 424).
It follows from the above document that spending of approximately EUR 938 million
is projected for measures focusing on increased energy efficiency in Slovakia in the 2014-
2020 programming period. Under the Operational Programme ‘Quality of Environment’,
financial resources earmarked for the renovation of public buildings outside the Bratislava
Region amounting to between EUR 350 million and EUR 499 million may be spent on
27
proposed energy efficiency measures at central bodies of state administration as part of the
mandatory renovation of those bodies’ buildings. Following the exhaustion of financial
resources for the renovation of the buildings of central bodies of state administration outside
the Bratislava Region, at present there is no supporting financial mechanism to facilitate the
financing of the annual renovation required in the Bratislava Region.
Under the performance framework of Priority Axis 4 of the Operational Programme
‘Quality of Environment’, output indicators include the 2018 milestone objective to renovate
187 200 m2
of the floor area of public buildings beyond the level set by minimum
requirements, and the ultimate objective to renovate 1 248 000 m2 of floor area by 2023.
Besides opportunities to make use of European Union resources, it is also
essential to learn about the offers of European banking institutions in good time. One is the
MUNSEFF (Municipal Energy Efficiency Finance Facility) project.
MUNSEFF is a credit line to support the development of energy efficiency and
renewable energy sources among towns and municipalities in Slovakia. This support is
provided by the European Bank for Renovation and Development. The programme is
implemented in Slovakia by Slovenská sporiteľňa, a.s. and Všeobecná úverová banka, a.s.
The MUNSEFF programme enables applicants to receive a grant covering part of the
loan principal; the amount of the grant depends in part on the scope of the project or the
amount of energy saved. Under the MUNSEFF programme, multi-apartment buildings with
renovation projects aimed at increasing energy efficiency may apply for soft loans, grants or
the free assistance of a design consultant.
The minimum loan per project is EUR 20 000; the maximum loan is EUR 850 000.
Upon the successful completion of project implementation, a multi-apartment building may
obtain a grant covering between 10 % and 15 % of the overall loan. One of the requirements
is the attainment of energy savings of more than 30 % compared to the situation prior to
project implementation. Eligible applicants are municipalities, companies majority-owned by
municipalities, and private companies providing public services, e.g. theatre or swimming
pool operators. Resources may be granted for projects targeting the energy efficiency of
municipality-owned buildings (e.g. offices, health care, education, culture, sport and
relaxation, catering services, etc.). The eligible groups of measures are:
1. renovation of the space heating system, replacement of boilers, installation of heat
exchanger stations, modernisation of mechanical equipment (heaters, pumps, heat
recovery);
2. replacement of windows and doors (transparent building apertures) with more energy-
efficient versions;
3. thermal insulation of buildings (exterior walls, roof and ceiling of the service floor);
4. renovation of lighting;
5. installation of solar thermal panels.
4. Tasks for the construction industry, the business community, employment and
improved qualifications arising from the strategy
Residential and non-residential building renovation stakeholders are central bodies of
state administration, local government bodies, private owners and investors (represented by
28
facility managers), manufacturers of construction materials and the building technical
systems, designers (architects and civil engineers, represented by professional organisations),
contractors (represented by employer associations and expert associations), and research and
development centres.
New tasks associated with the renovation strategy for investors and designers are
incorporated into the strategy’s conclusions.
The aim of BUILD UP Skills – Slovakia (BUSS) was to prepare the initial steps of a
national strategy to improve training in construction with a specific focus on future
construction site specialists so that Slovakia and Europe would be able to meet the challenges
of a ‘green economy’, i.e. energy efficiency (reduced energy consumption), the use of
renewable energy sources, and reductions in greenhouse gas emissions, and, consequently, to
meet the 20/20/20 targets by 2020.
Employee skills, training and expertise are currently regarded as key attributes in the
further development of the construction industry. In construction, as in many other sectors,
increased productivity at all levels hinges on the skills of those in the industry.
In general, the manual skills of workers in the Slovak construction industry are
thought to be very good, and the professional reputation enjoyed by Slovak workers has also
spread abroad. The working morale of blue-collar professions, however, is much worse.
In the wake of transformation, the Slovak construction industry established the
organisational structure commonly used in other countries. A natural hierarchy of small (up to
49 employees), medium-sized (up to 250 employees) and large (over 250 employees)
enterprises was formed, the organisation of which mirrors the structure of contracting and
demand. Self-employed persons, i.e. lone traders, in the construction industry form a distinct
group in this respect. Each of these groups has found its natural place in the construction
market.
Based on their experience of the existing quality of work, employees project that, on
average, 31 % of their employees and 43 % of the employees of their subcontractors will
require additional training in the pursuit of professions related to deep renovations of the
existing stock of residential and non-residential buildings. In other words, with an average of
165 254 employees in the construction industry, almost 80 000 will need training.
Obstacles hindering progress towards the targets set up to the year 2020 have been
identified in two areas. The first area comprises barriers related to primary education and
training. The second area comprises barriers in today’s construction market that also reflect
current macroeconomic, sociological and demographic circumstances, because all of these
help to form the construction environment.
It is estimated that at least 40 % of building construction workers will need to undergo
training, take a course or otherwise improve their skills in the next few years.
A worker who has undergone training and embraced environmental changes can be
regarded as a representative of a green profession. Green professions include the following
expert areas of employment: bricklayers, plasterers, roofers and building structure assemblers
– responsible for construction work related to the insulation of the external skin and roof
cladding, and the installation and replacement of windows and doors, electricians – who
install solar panels, plumbers – who install solar collectors for hot water, construction workers
– who build energy-efficient buildings and wind power stations, and other workers involved
29
in the sustainable development of the clean and renewable energy of the future, as well as
specialists in verifying the functionality of energy-efficient building systems and facility
managers of energy-efficient buildings. These are professions associated with the sector
responsible for reducing energy consumption in buildings and for the use of renewable
energy, and with energy efficiency.
In recognition of the importance of increasing green profession skills, on 1 April 2015
the new Act No 61/2015 on vocational education and training and amending certain laws took
effect with a view to facilitating the smooth transition from education to the labour market
and increasing the prospects of secondary vocational school leavers in the labour market.
Starting in the 2015/2016 school year, the Vocational Education and Training Act enables
pupils to be trained in a dual education system. This lets employers prepare pupils precisely
and specifically for an occupation or a job according to their needs and requirements.
Dual education is a system of vocational education and training for an occupation that
provides pupils with the knowledge, abilities and skills necessary for that occupation. It is
characterised, in particular, by the close interlinking of comprehensive and vocational
theoretical education at a secondary vocational school with practical training at a particular
employer. In a dual education system, employers are not only able to enter the vocational
training process, but are also fully responsible for the organisation, content and quality of
practical training. To this end, they cover all the costs associated with the financing of
practical training. In order to maintain a unified scope and content of practical training in
individual fields of study, practical training will be held according to model curricula and
model syllabuses that have been developed in cooperation with the relevant professional and
trade organisations and are binding on employers active in the dual education system.
Dual education strengths
A highly skilled workforce, a smooth transition from education to the labour market.
The acquisition of skills and experience directly at the employer.
The acquisition of work habits directly in the production process at the employer.
Training using new technologies directly at the employer.
The employer’s responsibility for the practical part of the vocational training.
Employers have a say in the content of vocational training.
Vocational training programmes and their content are up to date, and can be flexibly
adjusted.
Verification of the knowledge and skills of school-leavers by the employer upon the
completion of studies.
Pupils choose an occupation and the employer who is to provide practical training.
Pupils are selected for dual education directly by the employer, and they are admitted
to the school with the employer’s consent.
Supervision of the dual education system by employer associations.
The pupil’s financial and material security is provided by the employer.
Close cooperation between the business, the school and the pupil.
Practically targeted curricula for each field.
The development of occupations linked to market needs.
A high probability of getting an employment contract with the employer.
30
4.1 Projects to improve qualifications in the construction sector after 2014
4.1.1 StavEdu project
The StavEdu project is a nationwide project aimed at creating a system to deepen
qualifications and further the training of construction craftsmen and workers in the energy
performance of buildings and the use of renewable energy sources in buildings. It is aimed in
particular at craftsmen and workers with a secondary vocational education in a technical field
(certificate of apprenticeship) who are interested in acquiring professional knowledge and
expertise in the energy performance of buildings and in the use of renewable energy sources
in buildings.
The aim is to expand knowledge about the types, properties and use of building
materials necessary to reduce the energy intensity of buildings, and required for technological
procedures and principles. To learn about the work activities used in synergy with
technological procedures, to be able to install thermal insulation systems on building façades,
including surface treatment. To learn about innovated technological processes and new
materials, to be able to use smart energy solutions, measurement methods, technologies, the
properties and structure of materials, including technical regulations. (Source: the website at
http://www.stavedu.sk)
4.1.2 ingREeS project
The ingREeS project, in its focus, priorities and planned activities, is a follow-up to
the European Build Up Skills (BUS) Initiative. The ingREeS project expands the scope of
the Roadmap, which was adopted in 2013 to develop the skills and knowledge of
construction workers in Slovakia, to include construction experts from middle and senior
management. This Roadmap set out key measures for the establishment of national
qualification frameworks and the education and training system, as well as other measures to
ensure the development of skills needed for energy efficiency in the construction industry, in
order to meet the EU energy targets by 2020.
The main target group of the project and the upcoming training programmes is
construction-sector experts at the middle and senior management levels in five professions
that, according to the Roadmap, are crucial to achieve energy targets by 2020:
1. site manager;
2. site supervisor;
3. civil engineers and architects;
4. building sustainability consultant;
5. persons professionally competent for the energy performance certification of
buildings.
The project’s second target group comprises experienced construction-sector
professionals working in the field of energy efficiency and the usability of renewable
sources, who have the potential to participate in the project as an external expert or
trainer.
31
The project’s third target group is made up of the relevant Slovak state, public and
professional institutions and organisations, as well as construction-sector companies and
employers, who will be invited to discuss incentive measures.
The ingREeS project introduces qualitative change to the system of li felong
learning in the construction sector, driving forward increased efficiency and participation
in educational activities. This project unites professional organisations and associations
bringing together the target groups with the vision of building a system of further
education for construction professionals at medium and senior levels of management.
Those who undergo this training will also have the skills and knowledge to meet European
standards, expectations and requirements.
4.1.3 The BIM phenomenon in the construction industry
The building information model is a revolutionary way of communication in the
preparation, construction and management of buildings (facility management). The
systematic push for the use of building information model technology in professional practice
by all those involved in the building process throughout the entire life cycle of a building will
save on investment and operating costs.
5. Review of the strategy’s implementation outputs
The Residential and Non-residential Building Stock Renovation Strategy, Slovak
Republic, is not a static or final document, nor was it intended as such. Rather, it is a
document that has the potential to be developed and encapsulate trends in this area. The
authors originally conceived it as a basis to work on a more specific stage for the renovation
of residential and non-residential buildings. The strategy for the renovation of residential and
non-residential buildings was meant to result in a long-term plan. This aim was dropped
because the long-term outlook for the renovation of residential and non-residential buildings
is provided by the strategy per se, which is and will be updated every three years, as required
of us by Section 9 of Act No 321/2014 on energy efficiency and amending certain laws.
Section 10 of that Act lays down a further obligation that influenced our decision not to draw
up a long-term plan. Specifically, the Ministry, in cooperation with central bodies of state
administration and public bodies, is to draw up an annual plan for the renovation of relevant
buildings in the following calendar year.
On this basis, since 2015 a ‘Plan for the Renovation of Relevant Buildings’ has been
drawn up and submitted to a Government session in June each year. That document is
dedicated to identifying buildings planned for renovation and the energy savings potential of
buildings.
6. Barriers and obstacles
A key task in the implementation of the renovation strategy is to achieve, in the very
short period between 2015 and 2020, the energy efficiency of buildings by gradually
tightening the requirements of the three energy levels of construction. This requires the
amendment of legal and technical regulations, new forms of support and sufficient awareness
among all building renovation stakeholders.
32
Well-known barriers in construction also apply to building renovation. These include
- poor energy and legal awareness on the part of owners;
- mixed building ownership (e.g. a residential part and a non-residential part);
- public procurement and tendering procedure geared primarily towards the lowest price;
- the poor quality and low price of design work;
- the low price and quality of execution of energy performance certificates;
- insufficient awareness among construction stakeholders regarding new requirements,
measures, construction products, etc.;
- the inadequate system for the training and acquisition of skills required for green
professions;
- the lack of lifelong learning for selected professions (e.g. designers);
- the lack of deep renovation (including the renovation of the technical equipment of
buildings);
- the lack of renovation of heat distribution systems, heat generators and sources used for
the preparation of hot water.
Low prices affect the quality and completeness of design documentation and therefore
have an adverse effect on the quality of the executed work. The low prices of energy
certificates mean that they cannot be drawn up objectively and, consequently, they cannot
present the true quality or information about the impact of the measures taken or draft
measures recommended for application in the future. The initial critical tasks to dismantle
these barriers are included in the strategy conclusions. Updating the strategy at three-year
intervals will make it possible to assess not only the extent to which these tasks have been
accomplished, but also to propose and approve other tasks leading to the elimination of these
obstacles.
7. Conclusions
The strategy has formed a framework in which to express public priorities in energy
efficiency and has provided the business community in the energy and construction industries
with an indication of the state’s long-term vision, thus contributing to the better planning of
investments and other action by private businesses.
It should be noted that the conclusions, the implementation date of which is ongoing,
have been fulfilled over the reporting period and it is assumed that their fulfilment will
continue in the coming period.
To fulfil Conclusions 3 to 6, a legislative framework was drawn up, organisational
conditions were created, methodical guidance and an informative environment were devised
to meet the tightened conditions for the energy performance of buildings. The conclusions
appear to have been fulfilled.
Conclusion 9 can be judged to have been fulfilled because ‘Principles for the Design
and Execution of ETICS Doubling’ were drawn up (ISBN 978-80-8076-126-4). The use of
research results paved the way for the application of new materials and procedures for the
improvement of buildings renovated in the past to bring them up to the level of the more
stringent requirements established for the energy performance of buildings.
33
Taking into account the facts presented in chapter 5 (Review of the strategy’s
implementation outputs), it would be fair to say that Conclusion 10 has not been formally
fulfilled in accordance with the content of the title mentioned in the conclusion, but that its
content has been fulfilled and will continue to be met in the coming period because it is a
long-term task. The Plan for the Renovation of Relevant Buildings was drawn up in
accordance with Act No 321/2014 on energy efficiency and amending certain laws.
34
Annexes
Annex 1
Terms and definitions associated with the renovation of residential and non-residential
buildings
Annex 2
Numbers of renovated residential buildings (apartments) supported under the housing
development scheme and the State Housing Development Fund
Annex 3
Underlying documentation from the 2011 Population and Housing Census on the scope of
renovation of multi-apartment and single-family buildings
Annex 4
Numbers of energy performance certificates issued for buildings undergoing major renovation
from 2010 to 2016
Annex 5
Cost-effective measures to improve the energy performance of buildings
Annex 6
Information on the stock of residential and non-residential buildings
Annex 7
Cost-optimal levels of minimum energy performance requirements for building
Annex 8
Summary of primary-energy-saving measures, their benefit and energy-saving potential in the
period from 2015, with an outlook up to 2030
35
Annex 1
Terms and definitions associated with the renovation of residential and
non-residential buildings
The long-term strategy uses terms related to the renovation of buildings that are incorporated
into Slovak legal and technical regulations following the recasting of Directive 2010/31/EU of
the European Parliament and of the Council of 19 May 2010 on the energy performance of
buildings (recast) and Directive 2012/27/EU of the European Parliament and of the Council of
25 October 2012 on energy efficiency, amending Directives 2009/125/EC and 2010/30/EU
and repealing Directives 2004/8/EC and 2006/32/EC.
Energy performance of a building: the amount of energy required to meet all energy needs
associated with the normal use of a building, in particular the amount of energy required for
space heating and hot water production, cooling and ventilation, and lighting (pursuant to
Section 3(1) of the Act3).
The energy performance of a building is determined by calculation, or by a calculation
using the energy consumption measured, and is expressed by numerical indicators of energy
demand within the building and primary energy. Primary energy is energy from renewable
and non-renewable sources which has not undergone any conversion or transformation
process (pursuant to Section 3(2) of the Act1).
Building: a roofed structure with walls in which energy is used to adapt the interior
environment; a building means a structure as a whole or a part thereof that has been designed
or modified for separate use (pursuant to Section 2(3) of the Act.4).
Energy performance of a public building: the ratio of annual energy consumption measured
in a public building to the total floor area of the public building (pursuant to Section 10(8) of
the Act2).
Energy efficiency: a process that contributes to an increase in energy efficiency or to a
reduction in the energy intensity of energy conversion, distribution or consumption, taking
into account technical, economic or operational changes or changes in the behaviour of end-
users and end-consumers (pursuant to Section 2(f) of the Act2).
Public building: a building owned or managed by a public entity (pursuant to Section 2(k) of
the Act2).
Relevant building: a building under a special regulation, managed by a central body of state
administration which, as at 1 January of the given calendar year, fails to comply with the
minimum energy performance requirements for buildings pursuant to a special regulation, and
which has a total floor area of more than 250 m² (pursuant to Section 10(2) of the Act2).
Renovated building: an existing building in which changes are made to the structures and
3 Act No 555/2005 on the energy performance of buildings, as amended.
4 Act No 321/2014 on energy efficiency and amending certain laws.
36
technical system so that, before the end of their lifetime, it will meet the essential
requirements for structures and an extension to the lifetime of the structure or parts of the
structure, usually without disrupting the use of the building, in which respect renovation,
depending on the scope, may be full or partial (according to STN 73 0540-2 Thermal
protection of buildings. Thermal performance of structures and buildings. Part 2:
Functional requirements (73 0540), Article 2.5).
Major renovation: structural alterations to an existing building that affect more than 25 % of
the surface of the building envelope, in particular involving insulation of the external skin and
roof cladding and the replacement of the original apertures (pursuant to Section 2(7) of the
Act1).
Major renovation can be carried out in one go or by means of successive (partial)
structural alterations. Major renovation constitutes the partial renovation of a building. If a
major renovation is carried out in progressive steps, each progressive step constitutes a partial
renovation of a building.
Substantial refurbishment: renovation of the technical system for the space heating, hot
water preparation, ventilation, cooling, and lighting of buildings and combinations thereof, the
investment costs of which exceed 50 % of the investment costs of the acquisition of a new
comparable building technical system (pursuant to Section 9(2)(b) of the Act2).
Deep renovation: the major renovation and substantial refurbishment of a building so that the
building can be classified under the minimum energy class required by law,1 taking into
account the life cycle of each element of the building, and taking place in a one-off or
progressive manner according to the design documentation (pursuant to Section 9(2)(a) of the
Act2).
Comprehensive renovation: the condition of a building is secured by structural alterations.
All structures and the technical system meet basic building requirements established by
applicable legal and technical regulations (according to STN 73 0540-2 Thermal protection of
buildings. Thermal performance of structures and buildings. Part 2: Functional
requirements (73 0540), Article 2.5).
Comprehensive renovation can be carried out in one go or gradually as a partial
renovation. Comprehensive renovation consists of major renovation, substantial
refurbishment, and the renovation of structures and technical systems not significantly
affecting the need for and consumption of energy in the building (the ensuring of static, user
and fire safety, hygiene and acoustic protection, e.g. the renovation of open and enclosed
balconies, the lightning rod, lifts, sewage system, waterproofing, floors, etc.).
Total floor area: the floor area of a storey, ascertained from the outside dimensions of the
building, without taking into account local protruding structures, such as pillars, ledges,
pilasters, local reductions in the thickness of the external skin, excluding the areas of open and
enclosed balconies and terraces; if the room headway covers two or more storeys, e.g. a
staircase or gallery, the total floor area is calculated as if the room were divided by a
horizontal structure on the plane of each storey (according to STN 73 0540-2 Thermal
37
protection of buildings. Thermal performance of structures and buildings.
Part 2: Functional requirements (73 0540), Article 2.11).
Annex 2
Table 1 Numbers of renovated residential buildings (apartments) supported by the
housing development scheme and the State Housing Development Fund
Form of support Period
Number of apartments Support provided
(euro) Multi-
apartment
buildings
Single-
family
buildings
Total
Removal of systemic
defects in a multi-
apartment building 2000 to 2013 141 860 0 141 860 101 715 800
Renovation of a
residential building 2014 to 2016 89 258 2 89 260 416 369 072
Insulated residential
building 2014 to 2016 - - - 191 804 194
Removal of systemic
defects in a multi-
apartment building 2014 to 2016 - - - 78 117 266
Total residential
buildings 231 118 2 231 120 518 084 872
Table 2 Scope and analysis of the renovation of a multi-apartment building with State
Housing Development Fund resources
Years
Renovation of a multi-apartment
building
Insulation of a multi-apartment building
Support
provided (euro)
Number of
apartments
Average
support per
apartment
Support provided
(euro)
Number of
apartments
Average
support per
apartment
2006 22 874 959 4 636 4 934 0 0 0
2007 31 562 531 8 219 3 840 0 0 0
2008 24 909 945 6 474 3 848 0 0 0
2009 26 090 530 7 208 3 620 70 242 012 14 740 4 765
2010 32 232 110 9 199 3 504 0 0 0
2011 52 036 646 12 537 4 151 16 542 296 3 735 4 429
2012 68 828 561 16 690 4 124 20 863 521 4 892 4 265
2013 82 146 773 18 993 4 325 24 002 665 6 618 3 627
2014 112 942 112 25 280 4 468 56 111 888.65 - -
2015 109 369 420 22 828 4 791 53 086 350.13 - -
2016 194 034 450 41 150 4 715 82 605 955.05 - -
Total 757 028 037 156 708 46 320
Table 3 Scope and analysis of the renovation of a single-family building with State
Housing Development Fund resources
Years
Renovation of a single-family building Insulation of a single-family building
Support provided
(euro)
Number of
apartments
Average
support per
apartment
Support provided
(euro)
Number of
apartments
Average
support per
apartment
2006 143 597 8 17 950 0 0 0
38
2007 196 043 12 16 337 0 0 0
2008 22 937 1 22 937 0 0 0
2009 46 674 2 23 337 645 396 36 17 928
2010 0 0 0 0 0 0
2011 54 938 2 27 469 139 038 10 13 904
2012 0 0 0 76 476 4 19 119
2013 0 0 0 18 536 1 18 536
2014 0 0 0 - - -
2015 23 090 2 11 545 23 090 2 11 545
2016 0 0 0 - - -
Total 487 279 27 119 575 Source: Ministry of Transport, Construction and Regional Development
Annex 3
1. Underlying documentation from the 2011 Population and Housing
Census on the scope of renovation of multi-apartment and single-family
buildings
The 2011 Census tracked a lot of new data, making it possible to compare data
obtained previously from other surveys. Form C. BUILDING DATA tracked twelve items:
1. building type (single-family building, multi-apartment building, accommodation
facility without an apartment);
2. occupancy;
3. form of ownership;
4. time of construction;
5. time of reconstruction;
6. number of storeys;
7. number of apartments in the building;
8. material of the load-bearing structure;
9. type of water connection;
10. type of sewer system;
11. thermal insulation;
12. gas connection.
The item ‘thermal insulation’ was important for comparison. Here, the explanatory
notes to the census form stated that a building is insulated if it has an insulated external skin
and, at the same time, the windows and doors have been modified to prevent heat loss. The
thermal insulation used may also be partial. This was to be indicated if only some parts or
walls of the building were insulated. The data were to be filled in by the home-owner, facility
manager, occupant or census commissioner.
The ‘time of reconstruction’ item was intended to indicate when the most recent
reconstruction of the building (horizontal or vertical extension, conversion) was completed.
According to the form’s explanatory notes, the insulation of a building (contrary to building
regulations) was also treated as a reconstruction. Regular maintenance work, including the
39
repair of a façade, the repair and replacement of roofing, the repair and replacement of minor
structures, such as partitions, the replacement of equipment, the replacement of windows, and
similar modifications, is not considered to be a reconstruction. If the building had not been
reconstructed (renovated), this also had to be indicated.
Table 1 Thermal insulation – single-family buildings
Slovakia, regions Thermal insulation – single-family buildings Total
yes partially no unidentified
Slovakia 145 470 116 273 509 548 198 069 969 360
Bratislava Region 20 009 8 132 25 014 14 068 67 223
Trnava Region 21 197 15 122 62 713 20 907 119 939
Trenčín Region 15 656 12 759 57 882 26 205 112 502
Nitra Region 20 329 16 573 91 478 32 239 160 619
Žilina Region 25 698 18 491 61 233 28 170 133 592
Banská Bystrica Region 11 710 13 085 70 253 31 751 126 799
Prešov Region 17 337 17 032 72 881 22 222 129 472
Košice Region 13 534 15 079 68 094 22 507 119 214
Source: 2011 Census, Statistical Office
Table 2 Thermal insulation – multi-apartment buildings
Slovakia, regions Thermal insulation – multi-apartment buildings Total
yes partially no unidentified
Slovakia 18 416 8 196 36 280 1 954 64 846
Bratislava Region 4 070 1 280 4 745 551 10 646
Trnava Region 1 619 586 3 949 189 6 343
Trenčín Region 1 912 1 043 5 263 222 8 440
Nitra Region 1 662 859 5 097 248 7 866
Žilina Region 2 763 1 102 3 238 171 7 274
Banská Bystrica Region 2 964 1 338 4 155 239 8 696
Prešov Region 1 804 1 111 4 500 159 7 574
Košice Region 1 622 877 5 333 175 8 007
Source: 2011 Census, Statistical Office
In order to use the information in Tables 1 and 2 to express major renovations of
single-family and multi-apartment buildings as a percentage, along with a lot of other
information, summary data on buildings and apartments as at 21 May 2011 needed to be
monitored:
Table 3
40
Numbers of buildings and
apartments
Single-family
buildings
Multi-apartment
buildings
buildings 969 360 64 846
total apartments 1 008 795 931 605
apartments occupied 856 147 877 993 Source: Data from the 2011 Census, prepared by the Building Insulation Association
The data obtained from Tables 1 and 2 are an indisputable benefit. These are the first
statistical data documenting the extent of single-family building renovations in Slovakia. Both
tables also provide data that make it possible to determine the extent of renovations in each
region.
Table 4
Region Renovations (%)
Single-family buildings Multi-apartment buildings
Slovakia 27.00 41.04
Bratislava Region 41.86 50.25
Trnava Region 30.28 34.76
Trenčín Region 25.26 35.01
Nitra Region 22.97 32.04
Žilina Region 33.08 53.13
Banská Bystrica Region 19.55 49.47
Prešov Region 26.55 38.49
Košice Region 24.00 31.21
Source: Data from the 2011 Census (Statistical Office), prepared by the Building Insulation Association
2. Expert estimate of the extent of thermal insulation in the years 1992 to
2012, and establishment of the procedure to determine this according to
the Building Insulation Association
The extent of thermal insulation is determined on the basis of a construction product
that copies the perimeter wall of the building during the insulation process, i.e. the expanded
polystyrene (EPS) EPS/F 70, as an ETICS component. EPS accounts for 85 % to 90 % of the
thermal insulation used in the thermal insulation composite system (ETICS).
This is a methodically determined expert estimate drawing on a range of variable data
on the consumption of foam polystyrene, such as EPS consumption, expressed as total tonnes,
the deduction of EPS exports, the deduction of EPS for fittings and packaging, the extent of
EPS in the construction industry, and, on this basis, the extent of EPS for façades, the share of
EPS waste, the bulk density of EPS, the average EPS thickness in ETICS, and a determination
41
of the extent of EPS 70F in m2 and the total extent of ETICS production.
The extent of total EPS production in the years 2001 to 2012 is represented by a graph
taken from the EPS Association in Slovakia.
EPS production (thousands of tonnes) in Slovakia in the years 2001 to 2015
Source: Slovak EPS Association
When determining the check conversion from m2 of EPS 70F to the number of
apartments in multi-apartment and single-family buildings, as well as non-residential
buildings, the basis was formed by the annual scope of EPS 70F from 2008 to 2011, which
was almost identical in each year (approximately 30 000 tonnes of EPS and approximately
8 million m2 of façades in Slovakia).
The annual conversion rate is as follows:
8 million m2 of façades (30 000 tonnes of EPS) represented
- 22 000 single-family buildings;
- 35 000 apartments in multi-apartment buildings;
- 5 000 new insulated single-family buildings; and
- 94 non-residential buildings;
all of different sizes, respecting the extent of construction in the regions of Slovakia.
3. Further steps in determining the extent of renovations up to and after
2020
The Building Insulation Association’s expert estimate of building renovation, by
reference to the progressively updated installation of thermal insulation on building façades
from 1992 to 2012, can be compared with data from the 2011 Census, and a suitable
correction can be established for the original figures. Consequently, the extent of renovations
of multi-apartment and single-family buildings from 2011 to 2013 could be added to data
from the 2011 Census. It is currently possible to discuss the extent to which residential
buildings have been renovated. In the future, it will also be possible to focus in detail on the
EPS production in Slovakia (thousands of tonnes)
42
renovation of non-residential buildings, expressed through ETICS for the years 2005 to 2012
as approximately 2 387 500 m2 of exterior skin (this is not broken down into the individual
categories of non-residential buildings).
Annex 4
Numbers of energy performance certificates issued for buildings
undergoing major renovation from 2010 to 2016
Table 1 Numbers of energy performance certificates by building category and energy
class in 2010
Building category Energy class
Total
A B C D E F G
Single-family buildings 8 372 248 55 20 8 9 720
Multi-apartment buildings 0 356 350 29 4 1 0 740
Office buildings 1 58 62 21 6 6 3 157
Schools and school facilities 0 51 121 52 18 4 1 247
Hospitals 0 9 6 2 0 0 0 17
Hotels and restaurants 1 32 8 4 0 1 0 46
Sports halls and other buildings
intended for sport 0 3 6 4 2 0 0 15
Wholesale and retail trade
services buildings 0 26 13 5 5 0 1 50
Other mixed-purpose buildings 1 25 21 5 2 0 0 54
Total 11 932 835 177 57 20 14 2 046
Source: INFOREG
Table 2 Numbers of energy performance certificates by building category and energy
class in 2011
Building category Energy class
Total
A B C D E F G
Single-family buildings 8 540 295 77 24 6 9 959
Multi-apartment buildings 1 606 455 20 3 1 0 1 086
Office buildings 1 100 67 17 5 4 3 197
Schools and school facilities 1 48 142 55 15 8 5 274
Hospitals 0 13 5 0 0 0 0 18
Hotels and restaurants 1 33 6 3 2 0 0 45
Sports halls and other buildings
intended for sport 1 9 7 7 3 1 0 28
Wholesale and retail trade 2 28 18 5 2 3 2 60
43
services buildings
Other mixed-purpose buildings 1 40 27 8 2 0 1 79
Total 16 1 417 1 022 192 56 23 20 2 746
Source: INFOREG
Table 3 Numbers of energy performance certificates by building category and energy
class in 2012
Building category Energy class
Total
A B C D E F G
Single-family buildings 22 535 321 101 20 10 11 1 020
Multi-apartment buildings 1 843 429 20 4 0 0 1 297
Office buildings 1 93 58 14 2 1 0 169
Schools and school facilities 0 36 78 16 3 2 4 139
Hospitals 0 11 5 0 0 0 0 16
Hotels and restaurants 2 48 9 3 1 0 0 63
Sports halls and other buildings
intended for sport 0 3 6 2 0 0 0 11
Wholesale and retail trade
services buildings 3 42 18 4 1 2 0 70
Other mixed-purpose buildings 0 41 25 5 0 0 1 72
Total 29 1 652 949 165 31 15 16 2 857
Source: INFOREG
Table 4 Numbers of energy performance certificates by building category and energy
class in 2013
Building category Energy class
Total
A B C D E F G
Single-family buildings 27 638 391 108 32 12 17 1 225
Multi-apartment buildings 1 641 379 30 2 0 0 1 053
Office buildings 2 50 68 24 7 4 2 157
Schools and school facilities 1 26 43 17 2 4 2 95
Hospitals 1 12 6 3 1 0 0 23
Hotels and restaurants 1 25 15 1 1 0 0 43
Sports halls and other buildings
intended for sport 1 3 3 3 0 0 1 11
Wholesale and retail trade
services buildings 2 39 33 14 2 3 0 93
Other mixed-purpose buildings 4 39 36 8 1 0 0 88
Total 40 1 473 974 208 48 23 22 2 788
44
Source: INFOREG
Table 5 Numbers of energy performance certificates by building category and energy
class in 2014
Building category Energy class Total
A0 A1 B C D E F G
Single-family buildings 139 244 668 129 31 14 4 4 1 233
Multi-apartment buildings 77 41 791 158 22 9 1 1 1 100
Office buildings 2 4 75 38 12 3 1 1 136
Schools and school facilities 1 3 27 33 12 2
78
Hospitals
10 4 1
15
Hotels and restaurants 2 6 32 15 3 4 1
63
Sports halls and other
buildings intended for sport
1 2 1
1 5
Wholesale and retail trade
services buildings 1 9
52 32 9 3 2
108
Other mixed-purpose
buildings 2 6
54 27 4 1 1
95
Total 224 313 1 710 438 95 36 10 7 2 833
Source: INFOREG
Table 6 Numbers of energy performance certificates by building category and energy
class in 2015
Building category Energy class
Total
A0 A1 B C D E F G
Single-family buildings 150 284 693 123 40 10 6 3 1 309
Multi-apartment buildings 72 49 699 119 15 3 1 4 962
Office buildings 1 12 83 52 9 6
5 168
Schools and school
facilities 1
50 66 22 9 6 6 160
Hospitals
13 5 1
19
Hotels and restaurants 2 9 42 14 5 2
1 75
Sports halls and other
buildings intended for sport
1 8 1 1
11
Wholesale and retail trade
services buildings
3 58 33 8 3 3 3 111
Other mixed-purpose
buildings 1 4 46 14 1 2
68
45
Total 227 361 1 685 434 102 36 16 22 2 883
Source: INFOREG
Table 7 Numbers of energy performance certificates by building category and energy
class in 2016
Building category Energy class
Total
A0 A1 B C D E F G
Single-family buildings 168 391 656 126 37 9 7 2 1 396
Multi-apartment buildings 80 69 820 121 19 8 4 1 121
Office buildings 4 8 67 37 2 1
2 121
Schools and school
facilities 1 2 37 26 6 3 1 76
Hospitals 1 2 9 1
13
Hotels and restaurants 2 5 35 9 3 2
56
Sports halls and other
buildings intended for sport
1 5 4 3 1
14
Wholesale and retail trade
services buildings
7 52 32 12 2
2 107
Other mixed-purpose
buildings 1 8 49 13 1 3
75
Total 257 493 1 730 369 83 29 12 6 2 979
Source: INFOREG
Annex 5
Cost-effective measures to improve the energy performance of buildings
Cost-effective measures to improve the energy performance of buildings are
distinguished by building category. Their service life is taken into account for the specified
calculation period. In keeping with conditions under Commission Delegated Regulation (EU)
No 244/2012 of 16 January 2012 supplementing Directive 2010/31/EU of the European
Parliament and of the Council on the energy performance of buildings by establishing a
comparative methodology framework for calculating cost-optimal levels of minimum energy
performance requirements for buildings and building elements, a calculation period of 30
years for residential buildings and public buildings and 20 years for other buildings will be
factored in.
Table 1 Measures proposed for selected building categories
Building
category
Structure/
technical
system
Proposed measure Service life
(years)
Multi-apartment
building
External skin Change in thermal protection with insulation
where the thickness of thermal insulation in the ETICS
depends on the original condition and level of
requirements for the energy performance of buildings,
and respects fire safety requirements
25-30
46
Roof envelope Change in thermal protection where the thickness of
thermal insulation depends on the original condition
and level of requirements for the energy performance
of buildings, production of new waterproofing layer
25
Windows, doors Replacement of external windows and doors 30
Ceiling above
an unheated
space/
neighbouring an
unheated space
Change in thermal protection with surface treatment
30
Space heating Installation or replacement of thermostatic
valves 10
Measurement of heat consumption 10
Reduction in the temperature gradient of the heating
system
Improvement in the thermal insulation of distribution
systems 20
Hydraulic regulation 10
Heat recovery (recuperation) systems 20
Replacement of pumps with pumps with frequency
converters 15
Replacement of radiators 30
New or upgraded district heating 30
Replacement of boilers with condensing boilers (if
there is a separate boiler room) 20
Replacement of boilers with condensing boilers using
solar collectors for space heating and hot water
preparation (if there is a separate boiler room)
20
Hot water
preparation
Replacement of taps with lever mixers 15
Replacement of taps with thermostatic and automatic
ones 15
Thermal insulation of risers and horizontal pipes with
max. heat loss of 10 W/m 20
Hydronic balancing of the distribution system 10
Replacement of pumps with pumps with frequency
converters 15
Reduction in the volume of storage tanks and increase
in their thermal insulation/replacement of tanks 15
Installation of solar collectors 15
Photovoltaic solar panels 10
Single-family
building
External skin Change in thermal protection with insulation
where the thickness of thermal insulation in the ETICS
depends on the original condition and level of
requirements for the energy performance of buildings
30
Roof envelope Change in thermal protection where the thickness of
thermal insulation depends on the original condition
and level of requirements for the energy performance
of buildings, production of new waterproofing layer
25
Windows, doors Replacement of external windows and doors 30
Ceiling above
an unheated
space/
neighbouring an
unheated space
Change in thermal protection with surface treatment
30
Space heating Same measures as for a multi-apartment building
apart from district heating 10-20
Hot water
preparation
Same measures as for a multi-apartment building 15
Office building External skin, Same measures as for a multi-apartment building 25
47
roof envelope,
internal
partitions,
external
windows and
doors
Space heating Same measures as for a multi-apartment building, apart
from district heating 10-20
Installation of zone regulation 15
Introduction of night and weekend temperature
attenuation in heated rooms 5-10
Hot water
preparation
Same measures as for a multi-apartment building 15
Alternatively, removal of central water heating and
installation of local heating 20
Lighting Replacement of light sources with light fittings with
electronic ballast and higher optical efficiency 5
Change in the arrangement of lights 15
Installation of motion sensors 10
Installation of luminance sensors 10
Optimisation of intervals for the replacement and
cleaning of light fittings 3-5
Annex 6
Information on the stock of residential and non-residential buildings
1. Data on existing multi-apartment buildings
Data from the multi-apartment building database are reported as there are still no other
complete data in Slovakia that are of such an informative scope that they could replace data
from this database. By the end of 2004, there were 867 704 apartments in multi-apartment
buildings in Slovakia. The multi-apartment building database contains 92.3 % of all
apartments in multi-apartment buildings.
The multi-apartment building database includes data on the energy consumed on space
heating for each of the years from 1994 to 2003 for the entire housing stock. The average
annual energy consumption from 1994 to 2003 is reported in kWh/m² of total floor area.
In housing construction, 24 construction technologies were used, but when the
differences between regional variants of solutions and the varying types, including MS 5 and
MS 11, are considered, the figure is 39; when terrace houses, point houses and tower blocks
are taken into account, 60 technologies were used (excluding T 20 and 22, VNB, B70/R and
brick houses). As one multi-apartment building built as a whole in the P 1.24 complex in
Bratislava and one section in Spišská Nová Ves, to which the same construction principles
were applied as those to P 1.14-7.5RP multi-apartment buildings, had already been renovated
(insulated), they were not taken into account when the number of technologies applied in
housing construction was being considered. Inspections also found different solutions for
multi-apartment buildings, e.g. T 06 B Žilina with protruding staircases and prefabricated
enclosed balconies ending in an attic, the T 06B Nitra on plinths, etc.
Table 1 Distribution of housing construction by external skin technology
Group of
multi-
apartment
Time of
construction
Types,
design systems,
structural systems
48
buildings
1 up to 1955,
1956-1970
T 11-16, T 01 -03
PV-2
2 1956-1970 BA, G 57, LB (MB), MS 5, MS 11, T 06 B (KE, NA, BA, BB,
ŽA), T 08 B, K 61, NMB (VMB), PD-62
3 1971-1983 ZT, ZTB, BA-BC, B-70, BA-NKS
4 1984-1992 P 1.14-6.5RP, P 1.14-7.5RP, PS-82 (TT, PP, ŽA, BB)
U-65, P 1.15, BA NKS-S, P 1.24
Table 2 Basic geometric data on multi-apartment buildings Form
factor
Built-up
volume
Total
floor
area
Buildin
g
envelop
e area
Windo
w area
Windo
w area
Extern
al skin
area
Extern
al skin
area
Roof
area
Roof
area
1/m m3 m
2 m2 m
2 % m2 % m
2 % Average 0.7968 762 251 579 47 8.1 217 38.7 162 27.2
Median 0.7536 696 228 508 41 7.7 216 37.4 141 27.5
Minimum 0.6149 260 87 279 15 4.1 94 17.8 69 18.2
Maximum 1.1115 1907 530 1500 125 12.8 449 57.7 574 38.3
A statistical analysis of the parameters from which the energy consumption is derived
indicates that the year of final approval is the third most influential factor in terms of energy
consumption. Bearing in mind how requirements regarding the thermal performance of
envelopes have evolved, it is advisable to divide existing multi-apartment buildings into those
built up to 1983 (inclusive) and those built after 1983, when a more stringent thermal
technology standard entered into force and prompted a change in external skin technology.
Table 3 Average heat consumed on space heating by structural system group Type,
construction
system,
structural
system group
Heat consumed on space heating in the years
in kWh/(m².a)
Average
annual heat
consumption
in the years
1994 to 2003 1994 1995 1996 1997 1998 1999 2000 2001 2002 2003
brick and pre-
assembled
masonry panels
132.6 139.9 151.5 143.2 130.7 126.1 116.7 128.1 125.2 123.3 131.7
single-layer
panel 112.9 117.6 129.4 120.5 108.4 105.1 96.0 106.5 103.2 103.0 110.3
layered panel 123.1 128.8 137.1 128.9 117.0 114.9 104.9 114.4 110.7 110.0 119.0
panel 103.2 110.3 117.6 109.3 98.3 94.6 86.6 95.7 90.2 90.9 99.7
atypical
buildings 120.0 118.4 92.8 83.5 94.7 101.9
other,
unspecified 110.2 118.5 111.3 101.2 99.5 97.8 88.9 103.5 133.5 93.7 105.8
National
average 116.6 122.9 134.3 125.8 113.1 109.8 100.3 111.6 107.3 106.3 114.8
Areas determined by the outside temperature are also characteristic of areas with
different conditions during the winter period, affecting the energy consumed on space heating.
49
The number of buildings, apartments, sections, and the total floor area are shown for each
outside air design temperature in the table below.
Table 4 Number of buildings, apartments, sections and specific area by outside air
design temperature
Outside air
design
temperature (°C)
Number of
buildings
Number of
apartments
Number of
sections
Total floor area
(m2)
-11 7 484 308 252 17 995 25 170 252
-12 1 059 36 210 2 842 2 925 353
-13 4 307 163 195 10 438 13 192 946
-14 516 21 805 1 833 1 823 699
-15 5 290 186 437 13 262 15 427 402
-16 2 409 71 320 4 937 5 804 761
-17 491 10 122 907 809 150
-18 144 3 019 252 244 078
-19 23 274 30 24 025
Slovakia – total 21 723 800 634 52 496 65 421 666
2. Data on existing single-family buildings
Single-family buildings may have a maximum of three apartments according to Act
No 50/1976 on spatial planning and building rules (the Building Act), as amended.
Residential buildings with a larger number of apartments are considered to be multi-apartment
buildings. These data are published by the Statistical Office of the Slovak Republic according
to the results of the 2001 Population and Housing Census.
Table 5 Permanently occupied single-family buildings with apartments, by time of
construction and number of apartments
Permanently
occupied single-
family buildings and
their technical
facilities
Buildings with number of all apartments
1 2 3 Total
Up to 1899 18 849 747 211 19 807
1900-1919 26 707 831 208 27 746
1920-1945 85 367 2 726 384 88 478
1946-1960 161 136 4 590 292 166 018
1961-1970 159 149 7 042 278 166 469
1971-1980 127 451 8 699 354 136 504
1981-1985 54 101 2 253 113 56 467
1986-1990 47 837 1 353 43 49 233
1991-1995 33 118 1 045 42 34 205
1998-1999 22 643 953 78 23 674
2000 or later 7 315 311 17 7 643
Unidentified 15 441 802 68 16 311
Total permanently
occupied buildings 759 114 31 352 2 088 792 555
50
The heat losses of single-family buildings affect the geometric properties of those buildings.
The data are presented in the following table.
Table 6 Average geometric data on single-family buildings
Subcategory
Form
factor
Built-
up
volume
Total
floor
area
Envelop
e area
Windo
w area
Externa
l skin
area
Roof
area
1/m m3 m
2 m
2 m
2 m
2 m
2
All single-family buildings 0.7536 696 228 508 41 216 141
Single-storey single-family
buildings 0.9879 459 138 448 30 139 138
Single-family buildings with
two or more storeys 0.7293 730 256 539 48 226 145
3. Data on existing non-residential buildings
At present there are only data from a database detailing non-residential buildings
owned by central and local government authorities.
Table 7 State-owned non-residential non-manufacturing buildings broken down by
purpose of use
Purpose of use Number of
buildings
Share of total
number
(%)
Built-up volume
of buildings
m³
Share of total
built-up volume
(%)
Schools 6 943 45.0 58 382 303 50.9
Commerce and services 156 1.0 680 090 0.6
Healthcare facilities 1 293 8.4 15 197 903 13.2
Cultural facilities 525 3.4 3 071 713 2.7
Office buildings 2 556 16.6 14 365 517 12.5
Accommodation 1 317 8.5 11 814 638 10.3
Sports 126 0.8 810 218 0.7
Railway stations and
airports 7 0.0 92 991 0.1
Post offices 440 2.9 966 192 0.8
Other 2 072 13.4 9 322 087 8.1
Total 15 435 100.0 114 703 652 100.00
Of which primary
schools 2 513 16.3 26 549 348 23.1
Table 8 Average heat consumed on space heating by purpose of use
Purpose of use
Energy consumed on space heating in the years
in kWh/(m3.a) Average consumption
in the years 1994 to
2003 1994 1995 1996 1997 1998 1999 2000 2001 2002 2003
Schools 51.2 51.8 53.7 52.7 51.4 50.9 46.8 51.1 49.5 50.7 51.0
51
Commerce and
services 54.5 54.3 62.6 60.4 57.3 50.2 51.5 53.0 48.4 62.9 55.5
Healthcare facilities 59.7 59.5 79.0 75.9 71.2 71.9 68.1 70.6 65.1 61.7 68.3
Cultural facilities 47.3 45.8 46.3 46.6 45.4 43.7 37.7 41.1 33.3 39.6 42.7
Office buildings 56.7 59.3 61.6 60.1 58.2 57.8 53.0 56.7 54.7 57.8 57.6
Accommodation 57.4 59.7 62.2 60.6 59.4 60.0 57.9 62.0 57.4 58.7 59.5
Sports 48.8 46.8 49.1 47.8 44.0 46.3 42.5 42.9 37.5 37.0 44.3
Railway stations
and airports 46.2 46.2
Post offices 62.9 63.2 65.4 63.9
Other 53.7 53.8 61.4 58.8 57.5 58.0 55.4 58.3 57.5 56.3 57.1
Average for all
buildings 52.8 54.0 58.3 56.9 55.2 54.9 51.1 55.4 54.7 58.3 55.2
Primary schools 49.4 49.5 50.9 50.3 48.4 47.7 42.6 46.9 47.3 58.3 49.1
Non-residential non-manufacturing buildings are characterised by their division into
individual construction periods, taking into account the differences in requirements, in
particular those regarding the thermal performance of structures, as well as developments in
the material composition and structural design, as follows:
- up to 1950, brick structures and primarily sloping roofs (wooden trusses);
- 1951 to 1970, development of prefabrication systems, application of concrete with
lightweight fillers and lightweight concrete (porous concrete), almost exclusive use of
flat roofs, installation of double-glazing;
- 1971 to 1983, application of layered cladding, installation of aluminium double-glazed
windows, unless wooden, flat roof structures;
- post-1983, improvements in the thermal performance of structures in connection with
requirements of the revised thermal performance standard by proving the design
values; the calculation methods did not take into account the influence of the design
used for the details, resulting in higher thermal losses, especially at contact areas on
the external skin.
Table 9 Average heat consumed annually on space heating by time of construction
Year of final
approval
Heat consumed on space heating in the years
in kWh/(m3.a)
Average
consumpti
on
for 1994-
2003 1994 1995 1996 1997 1998 1999 2000 2001 2002 2003
Not specified 66.0 65.1 69.6 69.0 70.4 74.5 65.0 73.6 59.6 73.3 68.6
Up to 1950 49.2 50.8 56.1 55.2 53.3 53.7 50.0 53.6 52.5 55.6 53.0
1951-1970 54.0 54.8 59.3 57.5 55.0 54.2 51.0 55.9 56.1 60.0 55.8
1971-1983 54.7 55.5 59.1 57.5 56.0 54.9 50.8 55.4 55.1 58.6 55.8
1984-1992 49.7 52.1 55.8 53.9 52.2 52.9 49.5 52.5 52.7 56.3 52.8
Post-1992 47.9 50.6 57.7 56.6 55.3 54.6 51.5 55.0 55.0 56.0 54.0
Average for all
buildings 52.8 54.0 58.3 56.9 55.2 54.9 51.1 55.4 54.7 58.3 55.2
52
The heat consumed on space heating in individual years is influenced by the frequency
of low outside air temperatures during the heating season, as well as by the total number of
degree days.
Table 10 Average heat consumed annually on space heating by outside air design
temperature
Outside air
design
temperature
°C
Heat consumed on space heating in the years
in kWh/(m3.a)
Average
consumpti
on
in
1994-2003 1994 1995 1996 1997 1998 1999 2000 2001 2002 2003
From -11 to
-13 52.1 53.8 57.8 56.4 54.9 55.0 51.3 55.3 53.8 56.7 54.7
From -14 to
-16 52.7 53.4 57.8 56.3 54.5 53.5 49.4 54.0 54.1 58.6 54.4
-17 or less 63.3 63.1 69.5 67.9 65.6 67.7 63.3 69.4 72.4 75.7 67.8
Average 52.8 54.0 58.3 56.9 55.2 54.9 51.1 55.4 54.7 58.3 55.2
Annex 7
Cost-optimal levels of minimum energy performance requirements for
buildings
Eleven reference buildings were proposed by means of selection according to defined
features (building category, construction period, size, availability of underlying design
documentation), using the database of residential and non-residential buildings, and based on
statistical analysis methods. In addition to the set obligation to propose two reference
buildings from the existing stock and one reference new building, representing the categories
of multi-apartment buildings, single-family buildings and office buildings, one reference
building was proposed that represented school buildings.
The packages of measures included measures complying with the applicable
requirements set for the level of low-energy construction, the level of ultra-low-energy
construction and nearly zero-energy buildings according to STN 73 0540-2 Thermal
protection of buildings. Thermal performance of structures and buildings. Part 2: Functional
requirements (73 0540). All packages, including the package with the optimal structural
properties under consideration, were used to determine primary energy and life cycle costs,
including the net present value. The effect of recuperation was also examined. Recuperation
was excluded from the package because of its cost and technical complexity.
For each reference building, 5 to 12 packages/variants of measures are used. A
separate package comprises a reference case characterised by the initial situation for existing
buildings and a package characterised by requirements applicable to new buildings. Variant
solutions were proposed for each level of thermal protection for structures (e.g. 12 variants for
the thermal protection of the external skin, taking into consideration different thicknesses of
thermal insulation, ranging from 40 mm to 240 mm with additional thermal protection by
means of a thermal insulating composite system). The value of the heat transfer coefficient
took into account the original quality of the external skin, roof envelope and internal partitions
between heated and non-heated spaces. Products characterised by the heat transfer coefficient
53
of the frame and the glazing (Uf, Ug, Uw in W/(m2.K)), the solar energy throughput g (-) and
the linear loss coefficient of the glazing spacer bar were selected for individual variants of the
change in the thermal performance of the apertures. Heat generation variants (seven variants,
e.g. district heating running on natural gas, wood chips, combined heat and power generation,
a condensing boiler running on gas, a wood pellet boiler, an air - water heat pump, a ground -
air heat pump) and variants for hot water production and cold production were considered.
The variants were used in five of the packages under assessment, of which Package 3 was
analysed using properties of structures with defined cost-optimal values. For the lighting, the
cost optimality of the measures was analysed separately and compared with the energy
requirement. The variant chosen was applied in all packages of proposed measures when
determining the net value.
The results of the calculations indicate that the global costs are different from the
macroeconomic and financial perspectives, but the optimal position is not changed by this
fact. The national benchmark considered for Slovakia to compare the calculated cost-optimal
levels with the current minimum energy performance requirements is a level from the
financial perspective (a microeconomic level), and therefore includes VAT and disregards the
costs of CO2 emissions.
54
Table 1 Resultant cost-optimal values for the minimum requirements regarding the
thermal performance of structures – the maximum heat transfer coefficient
values for a structure (U)
Structure
Selection of
cost
optimum U
[W/(m2.K)]
Requirements
after 2013
(standardised
value)
[W/(m2.K)]
Requirements
after 2015
(recommended
value)
[W/(m2.K)]
Cost
optimum –
rounded
[W/(m2.K)]
External skin (O1) 0.209 0.32 0.22 0.21
Difference compared to
requirement
-53 % -5 %
Roof (O2) 0.177 0.20 0.10 0.18
Difference compared to
requirement
-13 % 44 %
Interior partitions for top-down
heat flow for a difference in
temperature of up to 20 K (O3)
0.310 0.75 0.50 0.31
Difference compared to
requirement
-142 % -61 %
Windows (O4) 0.836 1.40 1.00 0.90
g – solar radiation transmittance 0.620 0.62
Difference compared to
requirement
-67 % -20 %
Table 2 Resultant cost-optimal values for the minimum energy performance requirements –
primary energy
Building category
Selection of cost
optimum
[kWh/(m2.a)]
Requirements for a
reference building
after 2013
[kWh/(m2.a)]
Requirements
after 2015
[kWh/(m2.a)]
Residential buildings 86 126 63
Difference compared to requirement -47 % 27 %
Single-family buildings 131 216 108
Difference compared to requirement -65 % 17 %
Office buildings (excluding cooling) 94 154 77
Difference compared to requirement -64 % 18 %
Office buildings (with cooling) 137 240 120
Difference compared to requirement -75 % 12 %
Educational buildings – schools 85 136 68
Difference compared to requirement -61 % 20 %
Sports buildings 104 152 76
Difference compared to requirement -46 % 27 %
55
Annex 8
Summary of primary-energy-saving measures, their benefit and energy-saving potential in the period from 2015,
with an outlook up to 2030
Name of measure/Year 2015 2016 2017 2018 2019 2020 2021 2022 2023 2024 2025 2026 2027 2028 2029 2030
Renovation of multi-apartment buildings
LELC: 15000 15000 15000 20000 20000 20000 20000 20000 20000 20000 20000 20000 20000 20000 19000 17000
- estimated saving [GWh] 54 54 54 72 72 72 72 72 72 72 72 72 72 72 68.4 61.2
- annual counting of savings [GWh] 108 162 234 306 378 450 522 594 666 738 810 882 954 1022.4 1083.6
ULELC: 1000 1000 2000 2000 3000 5000 5000 5000 5000 5000 5000 7000 7000 7000 8000 10000
- estimated saving [GWh] 5.4 5.4 10.8 10.8 16.2 27 27 27 27 27 27 37.8 37.8 37.8 43.2 54
- annual counting of savings [GWh] 10.8 21.6 32.4 48.6 75.6 102.6 129.6 156.6 183.6 210.6 248.4 286.2 324 367.2 421.2
NZEB: 500 1000 1000 1000 2000 2000 2500 2500 3000 3000
- estimated saving [GWh] 0.6 0.7 0.9 1.1 1.2 1.4 1.6 1.9 2.1 2.4
- annual counting of savings [GWh] 1.3 2.2 3.3 4.5 5.9 7.6 9.5 11.6 14.0
External heat distribution systems 5 % 5 % 5 % 5 % 5 % 5 % 5 % 5 % 5 % 5 % 5 % 5 % 5 % 5 % 5 % 5 %
Renovation of single-family buildings
LELC: 5000 5000 8000 8000 10000 10000 15000 15000 15000 15000 15000 15000 15000 15000 15000 15000
- estimated saving [GWh] 102 102 163.2 163.2 204 204 306 306 306 306 306 306 306 306 306 306
- annual counting of savings [GWh] 204 367.2 530.4 734.4 938.4 1244.4 1550.4 1856.4 2162.4 2468.4 2774.4 3080.4 3386.
4 3692.4 3998.4
ULELC: 500 500 500 500 500 1000 1000 2000 2000 5000 5000 5000 5000 5000 5000
- estimated saving [GWh] 15 15 15 15 15 30 30 60 60 150 150 150 150 150 150
- annual counting of savings [GWh] 30 45 60 75 105 135 195 255 405 555 705 855 1005 1155
NZEB 100 100 100 100 200 200 200 200 200
56
- estimated saving [GWh] 5.2 7.5 9.8 15.6 21.3 27.1 32.8 38.6 44.4
- annual counting of savings [GWh] 12.7 22.5 38.0 59.3 86.4 119.2 157.8 202.2
Name of measure/Year 2015 2016 2017 2018 2019 2020 2021 2022 2023 2024 2025 2026 2027 2028 2029 2030
Renovation of the office buildings of central bodies of state administration
LELC 9 9 9 9 9 9 4 4 4 4 4 4 4 4 4 4
- estimated saving [GWh] 0.7 0.7 0.7 0.7 0.7 0.7 0.3 0.3 0.3 0.3 0.3 0.3 0.3 0.3 0.3 0.3
- annual counting of savings [GWh] 1.3 2.0 2.7 3.4 4.0 4.3 4.6 4.9 5.2 5.5 5.8 6.1 6.4 6.7 7.0
ULELC 5 5 5 5 4 4 4 4 4 4
- estimated saving [GWh] 0.5 0.5 0.5 0.6 0.6 0.6 0.7 0.7 0.7 0.8
- annual counting of savings [GWh] 1.0 1.5 2.1 2.7 3.4 4.1 4.8 5.5 6.3
NZEB 1 1 1 1 1 1
- estimated saving [GWh] 0.1 0.1 0.1 0.1 0.1 0.1
- annual counting of savings [GWh] 0.2 0.4 0.5 0.6 0.7
Temperature attenuation for LELC 30 % 30 % 30 % 30 % 30 % 30 % 30 % 30 % 30 % 30 % 30 % 30 % 30 % 30 % 30 % 30 %
Renovation of schools and school facilities
LELC 20 20 20 20 20 20 10 10 10 10 10 10 10 10 10 10
- estimated saving [GWh] 2.2 2.2 2.2 2.2 2.2 2.2 1.1 1.1 1.1 1.1 1.1 1.1 1.1 1.1 1.1 1.1
- annual counting of savings [GWh] 4.4 6.6 8.8 11.1 13.3 14.4 15.5 16.6 17.7 18.8 19.9 21.0 22.1 23.2 24.3
ULELC 10 10 7 7 7 5 5 5 5 5
- estimated saving [GWh] 1.7 1.7 1.2 1.2 1.2 0.8 0.8 0.8 0.8 0.8
- annual counting of savings [GWh] 3.3 4.5 5.6 6.8 7.6 8.5 9.3 10.1 10.9
NZEB 3 3 3 5 5 5 5 5
- estimated saving [GWh] 0.5 0.5 0.5 0.9 0.9 0.9 0.9 0.9
- annual counting of savings [GWh] 1.4 2.3 3.2 4.1 5.0
Temperature attenuation for LELC 30 % 30 % 30 % 30 % 30 % 30 % 30 % 30 % 30 % 30 % 30 % 30 % 30 % 30 % 30 % 30 %
Explanatory notes: LELC – low-energy level of construction
ULELC – ultra-low-energy level of construction
57
NZEB – construction at the level of nearly zero-energy buildings